Resistance to auxinic herbicides

ABSTRACT

The invention provides methods of identifying herbicidal auxins. The invention further provides auxin-herbicide-resistant plants and genes conferring auxin-herbicide resistance. This invention also provides a method of identifying other proteins that bind picolinate auxins from additional plant species. The invention further provides a method to identify the molecular binding site for picolinate auxins. The invention also includes the use of the picolinate herbicidal auxin target site proteins, and methods of discovering new compounds with herbicidal or plant growth regulatory activity. The invention also includes methods for producing plants that are resistant to picolinate herbicidal auxins. Specific examples of novel proteins associated with herbicide binding include AFB5, AFB4, and SGT1b.

REFERENCE TO RELATED APPLICATIONS

This is a divisional of U.S. patent application Ser. No. 12/875,946, filed Sep. 3, 2010, which in turn claims the benefit of U.S. patent application Ser. No. 11/686,844, filed Mar. 15, 2007, and U.S. Provisional Application No. 60/783,015, filed Mar. 15, 2006, all of which are incorporated herein in their entirety.

FIELD OF THE DISCLOSURE

The present invention relates to the field of plant biology and specifically to methods of identifying herbicidal auxins and herbicide resistant plants, and to nucleotide sequences conferring herbicide resistance to plants, particularly resistance to picolinate class of auxinic herbicides.

BACKGROUND OF THE DISCLOSURE

The use of herbicides for weed control is an extremely valuable agricultural practice to protect the yield of crop plants and to manage the growth of vegetation in pastures and other sites. However the use of many herbicides is becoming problematic through the advent of field resistance and also from increased toxicological and environmental concerns associated with certain pesticidal chemistries and modes of action. Thus there is a continuing need for new herbicidal chemistries.

There are currently a limited number of herbicidal classes that have proven to exhibit the desired attributes for a beneficial modern herbicide such as low incidence of resistance development and low potential for toxicological side effects. One such class is the auxinic herbicides that include such compounds as 2,4-D and picloram. This class can be further subdivided into compounds that contain a picolinate moiety (e.g., picloram, aminopyralid, clopyralid), those that contain an aryloxyacetate moiety (e.g., 2,4-D, fluoroxypyr, triclopyr etc.) and others (e.g., dicamba). All of these compounds elicit plant symptoms similar to excessive treatment with the natural plant hormone indole acetic acid (IAA) and induce similar physiological events, eventually leading to plant death. Interestingly, the widespread use of auxinic herbicides for many years has not resulted in significant field resistance. In addition, the auxinic mode of action is specific to plants and many of the auxinic herbicides exhibit favorable environmental profiles. Thus methods for the discovery of new compounds that act via the auxinic mode of action would be of great benefit, particularly those with increased potency, wider spectrum, optimal soil persistency or low cost of manufacture.

Genes that confer resistance to certain herbicides have found utility in the development of herbicide-tolerant crops by transgenic or mutagenic selection methods. Many auxinic herbicides have broad spectrum herbicidal activity but their use is limited by the fact that the desired crop or pasture component species is sensitive to the herbicide. This is particularly the case for the picolinate class of auxinic herbicides. Thus there is an unfulfilled need for herbicide-tolerance mechanisms that would be applicable to the picolinate class of auxinic herbicides.

SUMMARY OF THE DISCLOSURE

The invention in various embodiments provides methods of identifying herbicidal auxins (reporter assays, co-crystal structures of picolinate auxins and other chemistries that interact with AFB 4, AFB5 or SGT1b. Also provided are auxin herbicide resistant plants and genes conferring auxin-herbicide resistance. This disclosure also provides a method of identifying other proteins that bind picolinate auxins from additional plant species. These proteins may be identified by sequence similarity with AFB5 or SGT1b, the picolinate auxin target proteins disclosed here.

The invention in various embodiments further provides a method to identify the molecular binding site for picolinate auxins on AFB4 and AFB5 by performing domain swap experiments between AFB5 and the closely related F-box protein TIR1. Both AFB5 and TIR1 participate in auxin signal transduction; however TIR1 does not significantly interact with certain picolinate auxins. The binding site for the picolinate auxins may be identified by combining different portions of AFB5 and TIR1 and assaying for picolinate auxin binding to the chimeric protein.

As discussed in more detail below, AFB4 is another AFB protein of the subject invention. AFB4 shares about 80% amino acid identity with AFB5. AFB4 and AFB5 homologs are distinct in various ways (at the sequence level and in light of their unique properties, for example) from TIR1 and previously known AFB proteins such as AFB 1, AFB2, and AFB3. AFB1 is about 45% identical to AFB4 and about 47% identical to AFB5. AFB3 is about 48% identical to AFB4 and about 49% identical to AFB5.

The disclosure also includes the use of the picolinate herbicidal auxin target site proteins in discovering new compounds with herbicidal or plant growth regulatory activity. In one embodiment, the proteins can be used in biochemical assays to identify compounds that effectively inhibit ligand-binding to the target protein or inhibit auxin functionality. In another embodiment the proteins may be crystallized in the presence or absence of the herbicide and the molecular structure of the proteins determined by X-ray crystallography. This structural information can be used to design or search for new chemical structures that effectively interact with the target protein.

The disclosure also includes methods for producing plants that are resistant to picolinate herbicidal auxins. This may be accomplished through the generation of transgenic plants with gene constructs that inhibit the expression of the target protein or by screening for plants that are resistant to the picolinate auxin and using molecular information about the gene encoding the target protein to identify the mutation responsible for the auxin resistance or in plant breeding experiments that may enable the movement of the resistance gene into other plant varieties.

Picolinate auxinic herbicides exert their herbicidal effects through specific interaction with certain proteins and these proteins do not interact significantly with other auxinic herbicides, such as 2,4-D. One such protein is AFB5. AFB5 shows sequence similarity to a reported auxin receptor, the F-box protein, TIR1, that has been shown to mediate the interaction of the natural hormone IAA (and the herbicide 2,4-D) to initiate the auxin signal transduction cascade (Dharmasiri et al., Nature 435:441-445, 2005; Kepinski and Leyser, Nature 435:446-451, 2005). TIR1 acts as the recognition component of an SCF E3-ubiquitin ligase complex that directs the proteosomal degradation of auxin-responsive transcriptional regulators. The advantage of the present invention is that AFB5 specifically mediates the interaction of picolinate herbicidal auxins and not IAA or 2,4-D such that loss of its function confers resistance to picolinate auxins specifically and stimulation of its function leads to a herbicidal signal cascade. Another protein discovered to have similar properties is SGT1b. This is also associated with SCF function and is involved in mediating protein-protein interactions. A feature of this invention is that SGT1b function is specifically involved in picolinate auxin action.

The foregoing and other features and advantages will become more apparent from the following detailed description of several embodiments, which proceeds with reference to the accompanying figures.

BRIEF DESCRIPTION OF THE FIGURES

FIGS. 1A-1D. Differential effects of auxins on root growth of mutants from complementation Groups 1 and 2. Root lengths of Arabidopsis seedlings were measured 8 days after seeding on plates containing a range of concentrations of the test compounds and are plotted as a percentage of the root length of untreated plants in the same experiment. Typical root lengths for untreated controls were 21, 21 and 24 mm for wild-type, Group 1, and Group 2 plants respectively. The symbols used for wild type, R009 from complementation Group 1 and R051 from complementation Group 2 are denoted in FIG. 1A. (FIG. 1A) DAS534, (FIG. 1B) 2,4-D, (FIG. 1C) picloram, (FIG. 1D) IAA.

FIGS. 2A-2J. DAS534-resistant mutants and complementation with AFB5 and SGT1b. (FIG. 2A) to (FIG. 2E) untreated seedlings, (FIG. 2F) to (FIG. 2J) seedlings grown in the presence of 5 nM DAS534. The primary visible effects at this sublethal concentration of auxin are loss of gravitropism, lack of cotyledon decurvature and increased hypocotyl elongation (FIG. 2F). Mutants R127 and R051 are resistant to this effect (FIG. 2G) and (FIG. 2I), whereas mutants transformed with the corresponding wild-type gene regain the response, (FIG. 2H) and (FIG. 2J). The R127 CsVMV:AFB5 line appears to have an increased response relative to Col-0 (FIG. 2H).

FIGS. 3A-3B. Map-based cloning of the resistance mutations in R009 and R051. The horizontal line represents the chromosome, the vertical hatched lines show the position of the markers used in fine mapping experiments. (FIG. 3A) mapping of R009, (FIG. 3B) mapping of R051.

FIGS. 4A-4C. Comparison of the amino acid sequences of six TIR1-related F-box proteins from Arabidopsis and COIL Sequences were aligned using CLUSTAL within the Vector NTI suite. The F-box domain is denoted by the hatched line and the N-terminal extension unique to AFB5 and AFB4 by the solid line. Identical residues in all five AFBs are shaded black, residues that have conservative substitutions in one or more AFBs are shaded gray. The sites of the three mutant alleles of AFB5 are shown in italics, and those previously described for TIR1 are shown with underlining (Ruegger et al., Genes Dev 12: 198-207, 1998; Alonso et al., Proc Natl Acad Sci USA. 100(5):2992-2997, 2003). AFB1 is gi|18412177, AFB2 is gi|18405102, AFB3 is gi|18391439, AFB4 is gi|42573021, AFB5 is gi|18423092, TIR1 is gi|18412567 and COI1 is gi|18405209.

FIGS. 5A-5C. Comparison of the effect of DAS534 and 2,4-D on previously characterized mutants. Measurements were performed as described in FIG. 2. Typical root lengths for untreated controls were 20, 39 and 31 mm for tir1-1, axr2-1 and axr1-3 plants respectively. (FIG. 5A) Effect of DAS534 on edm1 and R051. The deletion mutant line edm1 lacks seven genes (At4g11220 through At4g11280) including SGT1b (Tor et al., Plant Cell 14: 993-1003, 2002). Effect of DAS534 (FIG. 5B) and 2,4-D (FIG. 5C) on axr1-3, axr2-1 and tir1-1 compared with R009 and R051.

FIGS. 6A-6B. Mutation sites in the SGT1b (At4g11260) gene that confer resistance to DAS534. (FIG. 6A) The exons of SGT1b are shown as boxed regions. The mutations in R107, R051 and R118 occur at the 3′ splicing sites of introns 6 and 7 of the gene. (FIG. 6B) The nucleotide sequences of the 3′ intron-exon boundaries for introns 6 and exon 7 and for intron 7 and exon 8 are shown. The intron portion is shaded gray and the mutation sites are arrowed. The complete nucleotide sequences of At4g11260 can be found in gi|30698542 as the complement of sequences 6851273 through 6853848.

FIG. 7 illustrates a phylogenetic analysis showing that AFB5 (and four related AFBs, including AFB4) are distinct from previously characterized TIR1 (and six related proteins, including AFB1, AFB2, and AFB3). AtAFB14g03190 is gi|18412177, AtAFB2 3g26810 is gi|18405102, AtAFB3 1g12820 is gi|18391439, AtAFB4 4g24390 is gi|42573021, AtAFB5 At5g49980 is gi|18423092, AtTIR1At3g62980 is gi|18412567, Os XP 493919 is gi|50949123, Os CAD40545 is gi|21740736, Os NP 912552 is gi|34902412, Os XP 507533 is gi|51979370 and Pt AAK16647 is gi|13249030.

FIGS. 8A-8C show a comparison of the effect of a foliar application of 200 g/ha picloram (FIG. 8A), 200 g/ha aminopyralid (FIG. 8B) or 50 g/ha 2,4-D (FIG. 8C) on wild type Col-0 and mutant R009 Arabidopsis plants. Pictures were taken 12 days after treatment of 17-day old plants.

BRIEF DESCRIPTION OF THE SEQUENCES

The nucleic and amino acid sequences listed in the accompanying sequence listing are shown using standard letter abbreviations for nucleotide bases, and three letter code for amino acids, as defined in 37 C.F.R. 1.822. Only one strand of each nucleic acid sequence is shown, but the complementary strand is understood as included by any reference to the displayed strand. The Sequence Listing is submitted as an ASCII text file in the form of the file named “Sequence.txt,” which was created on Nov. 15, 2011, and is 85,301 bytes, which is incorporated by reference herein.

In the accompanying sequence listing:

SEQ ID NO: 1 provides the nucleic acid sequence for the Arabidopsis gene identified herein as AFB5 and being a picolinate auxin receptor and associated with resistance to this class of herbicides (gi|30695799:135-1994 Arabidopsis thaliana transport inhibitor response protein, putative (At5g49980) mRNA, complete cds).

SEQ ID NO: 2 provides the AFB5 protein sequence encoded by SEQ ID NO: 1 (gi|18423092|ref|NP_(—)568718.1| transport inhibitor response protein, putative [Arabidopsis thaliana]).

SEQ ID NO: 3 provides the nucleic acid sequence for the Arabidopsis gene identified herein as SGT1b and being associated with picolinate auxin binding and resistance (gi|17017309|gb|AF439976.11 Arabidopsis thaliana SGT1b (SGT1b) mRNA, complete cds).

SEQ ID NO: 4 provides the SGT1b protein sequence encoded by SEQ ID NO: 3 (gi|17017310|gb|AAL33612.1|AF439976_(—)1 SGT1b [Arabidopsis thaliana]).

SEQ ID NO: 5 provides the nucleic acid sequence for the Arabidopsis gene identified herein as AFB4 (gi|42573020|ref|NM_(—)202878.1|Arabidopsis thaliana ubiquitin-protein ligase AT4G24390 transcript variant AT4G24390.2 mRNA, complete cds).

SEQ ID NO: 6 provides the AFB4 protein sequence encoded by SEQ ID NO: 5 (gi|42573021|ref|NP_(—)974607.1|ubiquitin-protein ligase [Arabidopsis thaliana]).

SEQ ID NO: 7 provides the nucleic acid sequence of an AFB5 homolog from Oryza sativa (rice) (GenBank entry gi:34902411). (gi|34902411|ref|NM_(—)187663.11Oryza sativa (japonica cultivar-group), predicted mRNA).

SEQ ID NO: 8 provides the protein sequence encoded by SEQ ID NO: 7. (gi|34902412|ref|NP_(—)912552.1|Putative F-box containing protein TIR1 [Oryza sativa (japonica cultivar-group)]).

SEQ ID NO: 9 provides the nucleic acid sequence of another AFB5 homolog from Oryza sativa (rice) (GenBank entry gi:51979369). (gi|51979369|ref|XM_(—)507533.1| PREDICTED Oryza sativa (japonica cultivar-group), OJ1175_B01.8-1 mRNA).

SEQ ID NO: 10 provides the protein sequence encoded by SEQ ID NO: 9. (gi|51979370|ref|XP_(—)507533.1| PREDICTED OJ1175_B01.8-1 gene product [Oryza sativa (japonica cultivar-group)]).

SEQ ID NO: 11 provides the nucleic acid sequence of an AFB5 homolog from Populus (gi|13249029|gb|AF139835.1|AF139835 Populus tremula×Populus tremuloides F-box containing protein TIR1 (TIR1) mRNA, complete cds).

SEQ ID NO: 12 provides the protein sequence encoded by SEQ ID NO: 11 (gi|13249030|gb|AAK16647.1|AF139835_(—)1 F-box containing protein TIR1 [Populus tremula×Populus tremuloides]).

SEQ ID NO: 13 provides the amino acid sequence of the myc epitope.

DETAILED DESCRIPTION OF THE INVENTION

Terms

Unless otherwise indicated, all technical and scientific terms used herein have the same meaning as they would to one skilled in the art of the present invention. Practitioners are particularly directed to Sambrook et al. (Molecular Cloning, Cold Spring Harbor, 1989) and Ausubel et al., (Current Protocols in Molecular Biology, 1993), for definitions and terms of the art. It is to be understood that this invention is not limited to the particular methodology, protocols, and reagents described, as these may vary.

In order to facilitate review of the various embodiments of the invention, the following explanations of specific terms are provided:

As used herein, the term “herbicide” refers to a chemical compound employed to kill or suppress the growth of plants, plant cells and tissues or to prevent or suppress the germination and growth of plant seeds.

As used herein, the term “vector” refers to a nucleic acid construct designed for transfer between different host cells. An “expression vector” refers to a vector that has the ability to incorporate and express heterologous DNA fragments in a foreign cell. Many prokaryotic and eukaryotic expression vectors are commercially available. Selection of appropriate expression vectors is within the knowledge of those having skill in the art.

A “heterologous” nucleic acid construct or sequence has a portion of the sequence that is not native to the plant cell in which it is expressed. Heterologous, with respect to a control sequence refers to a control sequence (i.e. promoter or enhancer) that does not function in nature to regulate the same gene the expression of which it is currently regulating. Generally, heterologous nucleic acid sequences are not endogenous to the cell or part of the genome in which they are present, and have been added to the cell, by infection, transfection, microinjection, electroporation, or the like. A “heterologous” nucleic acid construct may contain a control sequence/DNA coding sequence combination that is the same as, or different from a control sequence/DNA coding sequence combination found in the native plant.

As used herein, the term “gene” means the segment of DNA involved in producing a polypeptide chain, which may or may not include regions preceding and following the coding region, e.g. 5′ untranslated (5′ UTR) or “leader” sequences and 3′ UTR or “trailer” sequences, as well as intervening sequences (introns) between individual coding segments (exons) and non-transcribed regulatory sequence.

As used herein, “recombinant” includes reference to a cell or vector, that has been modified by the introduction of a heterologous nucleic acid sequence or that the cell is derived from a cell so modified. Thus, for example, recombinant cells express genes that are not found in identical form within the native (non-recombinant) form of the cell or express native genes that are otherwise abnormally expressed, under expressed or not expressed at all as a result of deliberate human intervention.

As used herein, the term “gene expression” refers to the process by which a polypeptide is produced based on the nucleic acid sequence of a gene. The process includes both transcription and translation; accordingly, “expression” may refer to either a polynucleotide or polypeptide sequence, or both. Sometimes, expression of a polynucleotide sequence will not lead to protein translation. “Over-expression” refers to increased expression of a polynucleotide and/or polypeptide sequence relative to its expression in a wild-type (or other reference [e.g., non-transgenic]) plant and may relate to a naturally-occurring or non-naturally occurring sequence. “Ectopic expression” refers to expression at a time, place, and/or increased level that does not naturally occur in the non-altered or wild-type plant. “Under-expression” refers to decreased expression of a polynucleotide and/or polypeptide sequence, generally of an endogenous gene, relative to its expression in a wild-type plant. The terms “mis-expression” and “altered expression” encompass over-expression, under-expression, and ectopic expression.

The term “introduced” in the context of inserting a nucleic acid sequence into a cell, means “transfection”, or “transformation” or “transduction” and includes reference to the incorporation of a nucleic acid sequence into a eukaryotic or prokaryotic cell where the nucleic acid sequence may be incorporated into the genome of the cell (for example, chromosome, plasmid, plastid, or mitochondrial DNA), converted into an autonomous replicon, or transiently expressed (for example, transfected mRNA).

As used herein, a “plant cell” refers to any cell derived from a plant, including cells from undifferentiated tissue (e.g., callus) as well as plant seeds, pollen, propagules and embryos.

As used herein, the terms “native” and “wild-type” relative to a given plant trait or phenotype refers to the form in which that trait or phenotype is found in the same variety of plant in nature.

As used herein, the term “modified” regarding a plant trait, refers to a change in the phenotype of a transgenic plant relative to the similar non-transgenic plant. An “interesting phenotype (trait)” with reference to a transgenic plant refers to an observable or measurable phenotype demonstrated by a T1 and/or subsequent generation plant, which is not displayed by the corresponding non-transgenic (i.e., a genotypically similar plant that has been raised or assayed under similar conditions). An interesting phenotype may represent an improvement in the plant or may provide a means to produce improvements in other plants. An “improvement” is a feature that may enhance the utility of a plant species or variety by providing the plant with a unique and/or novel quality.

As used herein, a “mutant” polynucleotide sequence or gene differs from the corresponding wild type polynucleotide sequence or gene either in terms of sequence or expression, where the difference contributes to a modified plant phenotype or trait. Relative to a plant or plant line, the term “mutant” refers to a plant or plant line which has a modified plant phenotype or trait, where the modified phenotype or trait is associated with the modified expression of a wild type polynucleotide sequence or gene.

As used herein, the term “T1” refers to the generation of plants from the seed of T0 plants. The T1 generation is the first set of transformed plants that can be selected by application of a selection agent, e.g., an antibiotic or herbicide, for which the transgenic plant contains the corresponding resistance gene. The term “T2” refers to the generation of plants by self-fertilization of the flowers of T1 plants, previously selected as being transgenic. T3 plants are generated from T2 plants, etc. As used herein, the “direct progeny” of a given plant derives from the seed (or, sometimes, other tissue) of that plant and is in the immediately subsequent generation; for instance, for a given lineage, a T2 plant is the direct progeny of a T1 plant. The “indirect progeny” of a given plant derives from the seed (or other tissue) of the direct progeny of that plant, or from the seed (or other tissue) of subsequent generations in that lineage; for instance, a T3 plant is the indirect progeny of a T1 plant.

As used herein, the term “plant part” includes any plant organ or tissue, including, without limitation, seeds, embryos, meristematic regions, callus tissue, leaves, roots, shoots, gametophytes, sporophytes, pollen, and microspores. Plant cells can be obtained from any plant organ or tissue and cultures prepared therefrom. The class of plants which can be used in the methods of the present invention is generally as broad as the class of higher plants amenable to transformation techniques, including both monocotyledenous and dicotyledenous angiosperm as well as gymnosperm plants.

As used herein, the term “gene silencing” refers to lack of (or reduction of) gene expression as a result of, though not limited to, effects at a genomic (DNA) level such as chromatin re-structuring, or at the post-transcriptional level through effects on transcript stability or translation. Evidence suggests that RNA interference (RNAi) is a major process involved in transcriptional and posttranscriptional gene silencing. Because RNAi exerts its effects at the transcriptional and/or post-transcriptional level, it is believed that RNAi can be used to specifically inhibit alternative transcripts from the same gene.

As used herein, the terms “interfering with” or “inhibiting” (expression of a target sequence) refers to the ability of a small RNA, such as an siRNA or a miRNA, or other molecule, to measurably reduce the expression and/or stability of molecules carrying the target sequence. A target sequence can include a DNA sequence, such as a gene or the promoter region of a gene, or an RNA sequence, such as an mRNA. “Interfering with or inhibiting” expression contemplates reduction of the end-product of the gene or sequence, e.g., the expression or function of the encoded protein or a protein, nucleic acid, other biomolecule, or biological function influenced by the target sequence, and thus includes reduction in the amount or longevity of the mRNA transcript or other target sequence. In some embodiments, the small RNA or other molecule guides chromatin modifications which inhibit the expression of a target sequence. It is understood that the phrase is relative, and does not require absolute inhibition (suppression) of the sequence. Thus, in certain embodiments, interfering with or inhibiting expression of a target sequence requires that, following application of the small RNA or other molecule (such as a vector or other construct encoding one or more small RNAs), the sequence is expressed at least 5% less than prior to application, at least 10% less, at least 15% less, at least 20% less, at least 25% less, or even more reduced. Thus, in some particular embodiments, application of a small RNA or other molecule reduces expression of the target sequence by about 30%, about 40%, about 50%, about 60%, or more. In specific examples, where the small RNA or other molecule is particularly effective, expression is reduced by 70%, 80%, 85%, 90%, 95%, or even more.

As used herein, the term “Post-Transcriptional Gene Silencing” (PTGS) refers to a form of gene silencing in which the inhibitory mechanism occurs after transcription. This can result in either decreased steady-state level of a specific RNA target or inhibition of translation (Tuschl, ChemBiochem, 2:239-245, 2001). In the literature, the terms RNA interference (RNAi) and posttranscriptional cosuppression are often used to indicate posttranscriptional gene silencing.

As used herein, the term “regulating gene expression” refers to the process of controlling the expression of a gene by increasing or decreasing the expression, production, or activity of an agent that affects gene expression. The agent can be a protein, such as a transcription factor, or a nucleic acid molecule, such as a miRNA or an siRNA molecule, which when in contact with the gene or its upstream regulatory sequences, or a mRNA encoded by the gene, either increases or decreases gene expression.

As used herein, the term “RNA interference” (RNAi) refers to gene silencing mechanisms that involve small RNAs (including miRNA and siRNA) are frequently referred to under the broad term RNAi. Natural functions of RNAi include protection of the genome against invasion by mobile genetic elements such as transposons and viruses, and regulation of gene expression.

RNA interference results in the inactivation or suppression of expression of a gene within an organism. RNAi can be triggered by one of two general routes. First, it can be triggered by direct cellular delivery of short-interfering RNAs (siRNAs, usually ˜21 nucleotides in length and delivered in a dsRNA duplex form with two unpaired nucleotides at each 3′ end), which have sequence complementarity to a RNA that is the target for suppression. Second, RNAi can be triggered by one of several methods in which siRNAs are formed in vivo from various types of designed, expressed genes. These genes typically express RNA molecules that form intra- or inter-molecular duplexes (dsRNA) or a “hairpin” configuration which are processed by natural enzymes (DICER or DCL) to form siRNAs. In some cases, these genes express “hairpin”-forming RNA transcripts with perfect or near-perfect base-pairing; some of the imperfect hairpin-forming transcripts yield a special type of small RNA, termed microRNA (miRNA). In either general method, it is the siRNAs (or miRNAs) that function as “guide sequences” to direct an RNA-degrading enzyme (termed RISC) to cleave or silence the target RNA. In some cases, it is beneficial to integrate an RNAi-inducing gene into the genome of a transgenic organism. An example would be a plant that is modified to suppress a specific gene by an RNAi-inducing transgene. In most methods that are currently in practice, RNAi is triggered in transgenic plants by transgenes that express a dsRNA (either intramolecular or hairpin, or intermolecular in which two transcripts anneal to form dsRNA).

As used herein, the term “RNA silencing” is a general term that is used to indicate RNA-based gene silencing or RNAi.

As used herein, the term “silencing agent” or “silencing molecule”, refers to a specific molecule, which can exert an influence on a cell in a sequence-specific manner to reduce or silence the expression or function of a target, such as a target gene or protein. Examples of silence agents include nucleic acid molecules such as naturally occurring or synthetically generated small interfering RNAs (siRNAs), naturally occurring or synthetically generated microRNAs (miRNAs), naturally occurring or synthetically generated dsRNAs, and antisense sequences (including antisense oligonucleotides, hairpin structures, and antisense expression vectors), as well as constructs that code for any one of such molecules.

As used herein, the term “small interfering RNA” (siRNA) refers to a RNA of approximately 21-25 nucleotides that is processed from a dsRNA by a DICER enzyme (in animals) or a DCL enzyme (in plants). The initial DICER or DCL products are double-stranded, in which the two strands are typically 21-25 nucleotides in length and contain two unpaired bases at each 3′ end. The individual strands within the double stranded siRNA structure are separated, and typically one of the siRNAs then are associated with a multi-subunit complex, the RNAi-induced silencing complex (RISC). A typical function of the siRNA is to guide RISC to the target based on base-pair complementarity.

As used herein, the term “transcriptional gene silencing” (TGS) refers to a phenomenon that is triggered by the formation of dsRNA that is homologous with gene promoter regions and sometimes coding regions. TGS results in DNA and histone methylation and chromatin remodeling, thereby causing transcriptional inhibition rather than RNA degradation. Both TGS and PTGS depend on dsRNA, which is cleaved into small (21-25 nucleotides) interfering RNAs (Eckhardt, Plant Cell, 14:1433-1436, 2002; Aufsatz et al., Proc. Natl. Acad. Sci. U.S.A., 99:16499-16506, 2002).

As used herein, “transgenic plant” includes a plant that comprises within its genome a heterologous polynucleotide. The heterologous polynucleotide can be either stably integrated into the genome, or can be extra-chromosomal. Preferably, the polynucleotide of the present invention is stably integrated into the genome such that the polynucleotide is passed on to successive generations. A plant cell, tissue, organ, or plant into which the heterologous polynucleotides have been introduced is considered “transformed”, “transfected”, or “transgenic”. Direct and indirect progeny of transformed plants or plant cells that also contain the heterologous polynucleotide are also considered transgenic.

Various methods for the introduction of a desired polynucleotide sequence encoding the desired protein into plant cells are available and known to those of skill in the art and include, but are not limited to: (1) physical methods such as microinjection, electroporation, and microprojectile mediated delivery (biolistics or gene gun technology); (2) virus mediated delivery methods; and (3) Agrobacterium-mediated transformation methods.

The most commonly used methods for transformation of plant cells are the Agrobacterium-mediated DNA transfer process and the biolistics or microprojectile bombardment mediated process (i.e., the gene gun). Typically, nuclear transformation is desired but where it is desirable to specifically transform plastids, such as chloroplasts or amyloplasts, plant plastids may be transformed utilizing a microprojectile-mediated delivery of the desired polynucleotide.

Agrobacterium-mediated transformation is achieved through the use of a genetically engineered soil bacterium belonging to the genus Agrobacterium. A number of wild-type and disarmed strains of Agrobacterium tumefaciens and Agrobacterium rhizogenes harboring Ti or Ri plasmids can be used for gene transfer into plants. Gene transfer is done via the transfer of a specific DNA known as “T-DNA” that can be genetically engineered to carry any desired piece of DNA into many plant species.

Agrobacterium-mediated genetic transformation of plants involves several steps. The first step, in which the virulent Agrobacterium and plant cells are first brought into contact with each other, is generally called “inoculation”. Following the inoculation, the Agrobacterium and plant cells/tissues are permitted to be grown together for a period of several hours to several days or more under conditions suitable for growth and T-DNA transfer. This step is termed “co-culture”. Following co-culture and T-DNA delivery, the plant cells are treated with bactericidal or bacteriostatic agents to kill or inhibit the Agrobacterium remaining in contact with the explant and/or in the vessel containing the explant. If this is done in the absence of any selective agents to promote preferential growth of transgenic versus non-transgenic plant cells, then this is typically referred to as the “delay” step. If done in the presence of selective pressure favoring transgenic plant cells, then it is referred to as a “selection” step. When a “delay” is used, it is typically followed by one or more “selection” steps.

With respect to microprojectile bombardment (U.S. Pat. No. 5,550,318 (Adams et al.); U.S. Pat. No. 5,538,880 (Lundquist et. al.), U.S. Pat. No. 5,610,042 (Chang et al.); and PCT Publication WO 95/06128 (Adams et al.); each of which is specifically incorporated herein by reference in its entirety), particles are coated with nucleic acids and delivered into cells by a propelling force. Exemplary particles include those comprised of tungsten, platinum, and preferably, gold.

An illustrative embodiment of a method for delivering DNA into plant cells by acceleration is the Biolistics Particle Delivery System (BioRad, Hercules, Calif.), which can be used to propel particles coated with DNA or cells through a screen, such as a stainless steel or Nytex screen, onto a filter surface covered with monocot plant cells cultured in suspension.

Microprojectile bombardment techniques are widely applicable, and may be used to transform virtually any plant species. Examples of species that have been transformed by microprojectile bombardment include monocot species such as maize (International Publication No. WO 95/06128 (Adams et al.)), barley, wheat (U.S. Pat. No. 5,563,055 (Townsend et al.) incorporated herein by reference in its entirety), rice, oat, rye, sugarcane, and sorghum; as well as a number of dicots including tobacco, soybean (U.S. Pat. No. 5,322,783 (Tomes et al.), incorporated herein by reference in its entirety), sunflower, peanut, cotton, tomato, and legumes in general (U.S. Pat. No. 5,563,055 (Townsend et al.) incorporated herein by reference in its entirety).

To select or score for transformed plant cells regardless of transformation methodology, the DNA introduced into the cell contains a gene that functions in a regenerable plant tissue to produce a compound that confers upon the plant tissue resistance to an otherwise toxic compound. Genes of interest for use as a selectable, screenable, or scorable marker would include but are not limited to GUS, green fluorescent protein (GFP), luciferase (LUX), antibiotic or herbicide tolerance genes. Examples of antibiotic resistance genes include the penicillins, kanamycin (and neomycin, G418, bleomycin); methotrexate (and trimethoprim); chloramphenicol; kanamycin and tetracycline. Polynucleotide molecules encoding proteins involved in herbicide tolerance are known in the art, and include, but are not limited to a polynucleotide molecule encoding 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) described in U.S. Pat. No. 5,627,061 (Barry, et al.), U.S. Pat. No. 5,633,435 (Barry, et al.), and U.S. Pat. No. 6,040,497 (Spencer, et al.) and aroA described in U.S. Pat. No. 5,094,945 (Comai) for glyphosate tolerance; a polynucleotide molecule encoding bromoxynil nitrilase (Bxn) described in U.S. Pat. No. 4,810,648 (Duerrschnabel, et al.) for Bromoxynil tolerance; a polynucleotide molecule encoding phytoene desaturase (crtl) described in Misawa et al. (Plant J. 4:833-840, 1993) and Misawa et al. (Plant Journal 6: 481-489, 1994) for norflurazon tolerance; a polynucleotide molecule encoding acetohydroxyacid synthase (AHAS, aka ALS) described in Sathasiivan et al. (Nucl. Acids Res. 18:2188-2193, 1990) for tolerance to sulfonylurea herbicides; and the bar gene described in DeBlock, et al. (EMBO J. 6:2513-2519, 1987) for glufosinate and bialaphos tolerance.

The regeneration, development, and cultivation of plants from various transformed explants are well documented in the art. This regeneration and growth process typically includes the steps of selecting transformed cells and culturing those individualized cells through the usual stages of embryonic development through the rooted plantlet stage. Transgenic embryos and seeds are similarly regenerated. The resulting transgenic rooted shoots are thereafter planted in an appropriate plant growth medium such as soil. Cells that survive the exposure to the selective agent, or cells that have been scored positive in a screening assay, may be cultured in media that supports regeneration of plants. Developing plantlets are transferred to soil less plant growth mix, and hardened off, prior to transfer to a greenhouse or growth chamber for maturation.

The present invention can be used with any transformable cell or tissue. By transformable as used herein is meant a cell or tissue that is capable of further propagation to give rise to a plant. Those of skill in the art recognize that a number of plant cells or tissues are transformable in which after insertion of exogenous DNA and appropriate culture conditions the plant cells or tissues can form into a differentiated plant. Tissue suitable for these purposes can include but is not limited to immature embryos, scutellar tissue, suspension cell cultures, immature inflorescence, shoot meristem, nodal explants, callus tissue, hypocotyl tissue, cotyledons, roots, and leaves.

Any suitable plant culture medium can be used. Examples of suitable media would include but are not limited to MS-based media (Murashige and Skoog, Physiol. Plant, 15:473-497, 1962) or N6-based media (Chu et al., Scientia Sinica 18:659, 1975) supplemented with additional plant growth regulators including but not limited to auxins, cytokinins, ABA, and gibberellins. Those of skill in the art are familiar with the variety of tissue culture media, which when supplemented appropriately, support plant tissue growth and development and are suitable for plant transformation and regeneration. These tissue culture media can either be purchased as a commercial preparation, or custom prepared and modified. Those of skill in the art are aware that media and media supplements such as nutrients and growth regulators for use in transformation and regeneration and other culture conditions such as light intensity during incubation, pH, and incubation temperatures that can be optimized for the particular variety of interest.

One of ordinary skill will appreciate that, after an expression cassette is stably incorporated in transgenic plants and confirmed to be operable, it can be introduced into other plants by sexual crossing. Any of a number of standard breeding techniques can be used, depending upon the species to be crossed.

Unless otherwise explained, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The singular terms “a,” “an,” and “the” include plural referents unless context clearly indicates otherwise. Similarly, the word “or” is intended to include “and” unless the context clearly indicates otherwise. Hence “comprising A or B” means including A, or B, or A and B. It is further to be understood that all base sizes or amino acid sizes, and all molecular weight or molecular mass values, given for nucleic acids or polypeptides are approximate, and are provided for description. Although methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present invention, suitable methods and materials are described below. All publications, patent applications, patents, and other references mentioned herein are incorporated by reference in their entirety. In case of conflict, the present specification, including explanations of terms, will control. In addition, the materials, methods, and examples are illustrative only and not intended to be limiting.

Identification of the Molecular Target Site for Picolinate Auxins.

Identification of Picolinate Auxin Resistant Mutants

Mutations conferring picolinate auxin-specific resistance can be identified by screening EMS-mutated M2 generation Arabidopsis seedlings for plants that can grow in the presence of a normally phytotoxic dose of a picolinate auxin. In a preferred embodiment, this can be a potent picolinate auxin such as a 6-phenyl substituted auxin as described in WO 03/011853 A1. Seedling survivors can be recovered and the progeny of these plants further tested for lack of resistance to 2,4-D. This effectively eliminates previously discovered mutants such as axr1 that have non-selective auxin-resistance. The chemical resistance spectrum of mutants that are not resistant to 2,4-D can be characterized by testing with a variety of different auxin herbicides. Genetic inheritance tests can determine if the mutations are dominant or recessive and the sites of the mutations can be determined by genetic mapping.

The invention provides Arabidopsis nucleic acids encoding picolinate auxin resistance genes AFB5 and SGT1b, as presented in SEQ ID NO: 1 (GenBank entry gi:30695799) and SEQ ID NO: 3 (GenBank entry gi:17017309). The invention further provides AFB5 and SGT1b protein sequences, as presented in SEQ ID NO: 2 (gi:18423092) and SEQ ID NO: 4 (gi:17017310), respectively. Nucleic acids and/or proteins that are orthologs or paralogs of Arabidopsis AFB5 and SGT1b have been identified and are described in Example 8 below. These orthologs or paralogs include AFB4 from Arabidopsis (SEQ ID NOs 5 and 6), homolog of AFB5 from Oryza sativa (rice) (GenBank entries gi|51979369 and gi134902411) (SEQ ID NOs 7, 8, 9 and 10) and an AFB5 homolog from Populus (GenBank entry gi|13249029 and gi|13249030) (SEQ ID NOs 11 and 12).

Across the entire length of the proteins, AFB4 and AFB5 share about 80% amino acid identity with each other and members of the AFB4 and AFB5 group all have at least 54% identity with all other members of the group. For example, the protein sequence from Populus has about 70% identity with AFB4 and about 73% identity with AFB5. All members of this group (SEQ ID NOs 5, 6, 7, 8, 9, 10, 11 and 12) are considered to be within, and usable according to, the subject invention.

As used herein, the term “AFB4, AFB5 and SGT1b polypeptides” refers to a full-length AFB4, AFB5 and SGT1b proteins or a fragments, derivatives (variants), or orthologs thereof that are “functionally active,” meaning that the protein fragments, derivatives, or orthologs exhibit one or more or the functional activities associated with the polypeptide of SEQ ID NO: 2, SEQ ID NO: 4 or SEQ ID NO: 6. In one preferred embodiment, a functionally active AFB4, AFB5 and SGT1b polypeptides cause an auxin resistant phenotype when mis-expressed in a plant. In a further preferred embodiment, mis-expression of the AFB4, AFB5 or SGT1b polypeptides causes an auxin-resistant phenotype in a plant. In another embodiment, a functionally active AFB4, AFB5 or SGT1b polypeptide is capable of rescuing defective (including deficient) endogenous AFB4, AFB5 or SGT1b activity when expressed in a plant or in plant cells; the rescuing polypeptide may be from the same or from a different species as that with defective activity. In another embodiment, a functionally active fragment of a full length AFB4, AFB5 or SGT1b polypeptide (i.e., a native polypeptide having the sequence of SEQ ID NO: 2, SEQ ID NO: 4 or SEQ ID NO: 6 or naturally occurring orthologs thereof) retain one of more of the biological properties associated with the full-length AFB5 or SGT1b polypeptides, such as signaling activity, binding activity, catalytic activity, or cellular or extra-cellular localizing activity.

Functionally active variants of full-length AFB4, AFB5 or SGT1b polypeptides or fragments thereof include polypeptides with amino acid insertions, deletions, or substitutions that retain one of more of the biological properties associated with the full-length AFB4, AFB5 or SGT1b polypeptides. These polypeptides may be referred to as modified wild-type proteins, allelic variants or truncated polypeptides. In some cases, variants are generated that change the post-translational processing of an AFB4, AFB5 or SGT1b polypeptides. For instance, variants may have altered protein transport or protein localization characteristics or altered protein half-life compared to the native polypeptide.

Mutant forms of AFB4, AFB5 or SGT1b are referred to as AFB4-m, AFB5-m and SGT1b-m, respectively. The expression of AFB4-m, AFB5-m and SGT1b-m in plants may cause resistance to picolinate auxins.

As used herein, the term “AFB4 nucleic acid”, “AFB5 nucleic acid” and “SGT1b nucleic acids encompass nucleic acids with the sequence provided in or complementary to the sequence provided in SEQ ID NO: 5, SEQ ID NO: 1 and SEQ ID NO: 3, respectively, as well as functionally active fragments, derivatives, or orthologs thereof. An AFB4, AFB5 or SGT1b nucleic acid of this invention may be DNA, derived from genomic DNA or cDNA, or RNA.

In one embodiment, a functionally active AFB4, AFB5 or SGT1b nucleic acid encodes or is complementary to a nucleic acid that encodes functionally active AFB4, AFB5 or SGT1b polypeptides, respectively. Included within this definition is genomic DNA that serves as a template for a primary RNA transcript (i.e., an mRNA precursor) that requires processing, such as splicing, before encoding the functionally active AFB4, AFB5 or SGT1b polypeptide. An AFB4, AFB5 or SGT1b nucleic acid can include other non-coding sequences, which may or may not be transcribed; such sequences include 5′ and 3′ UTRs, polyadenylation signals and regulatory sequences that control gene expression, among others, as are known in the art. Some polypeptides require processing events, such as proteolytic cleavage, covalent modification, etc., in order to become fully active. Accordingly, functionally active nucleic acids may encode the mature or the pre-processed AFB4, AFB5 or SGT1b polypeptide, or an intermediate form. An AFB4, AFB5 or SGT1b polynucleotide can also include heterologous coding sequences, for example, sequences that encode a marker included to facilitate the purification of the fused polypeptide, or a transformation marker.

In another embodiment, a functionally active AFB4, AFB5 or SGT1b nucleic acid is capable of being used in the generation of loss-of-function AFB4, AFB5 or SGT1b phenotypes, for instance, via antisense suppression, co-suppression, etc.

Identification of Orthologs that Bind Picolinate Auxins

Although AFB4, AFB5 and SGT1b genes were discovered in Arabidopsis and the gene and protein information disclosed herein is information derived from the Arabidopsis thaliana sequences, this invention is intended to encompass nucleic acid and protein sequences from other species of plants that are similar to AFB4 (At4g24390; SEQ ID NO: 6), AFB5 (At5g49980; SEQ ID NO: 2) and SGT1b (At4g11260; SEQ ID NO: 4). Some examples are provided below in Example 8.

In one preferred embodiment, a AFB4, AFB5 or SGT1b nucleic acid used in the methods of this invention comprises a nucleic acid sequence that encodes or is complementary to a sequence that encodes AFB4, AFB5 or SGT1b polypeptides having at least 50%, 60%, 70%, 75%, 80%, 85%, 90%, 95% or more sequence identity to the polypeptide sequence presented in SEQ ID NO: 2 or SEQ ID NO: 4.

In another embodiment an AFB4, AFB5 or SGT1b polypeptide of the invention comprises a polypeptide sequence with at least 50% or 60% identity to the AFB4, AFB5 or SGT1b polypeptide sequence of SEQ ID NO: 6, SEQ ID NO: 2 or SEQ ID NO: 4, respectively, and may have at least 70%, 80%, 85%, 90% or 95% or more sequence identity to the AFB4, AFB5 or SGT1b polypeptide sequence of SEQ ID NO: 6, SEQ ID NO: 2 or SEQ ID NO: 4, respectively. In another embodiment, AFB4, AFB5 or SGT1b polypeptides comprise a polypeptide sequence with at least 50%, 60%, 70%, 80%, 85%, 90% or 95% or more sequence identity to a functionally active fragment of the polypeptide presented in SEQ ID NO: 6, SEQ ID NO: 2 or SEQ ID NO: 4, such as a F-box domain or a SGT1 domain, respectively. In yet another embodiment, an AFB4, AFB5 or SGT1b polypeptide comprises a polypeptide sequence with at least 50%, 60%, 70%, 80%, or 90% identity to the polypeptide sequence of SEQ ID NO: 6, SEQ ID NO: 2 or SEQ ID NO: 4 over its entire length and comprises F box domain or SGT1 domain, respectively.

In another aspect, an AFB4, AFB5 or SGT1b polynucleotide sequence is at least 50% to 60% identical over its entire length to the AFB4, AFB5 or SGT1b nucleic acid sequences presented as SEQ ID NO: 5, SEQ ID NO: 1 or SEQ ID NO: 3, respectively, or nucleic acid sequences that are complementary to such a AFB4, AFB5 or SGT1b sequences, and may comprise at least 70%, 80%, 85%, 90% or 95% or more sequence identity to the AFB4, AFB5 or SGT1b sequence presented as SEQ ID NO: 5, SEQ ID NO: 1 and SEQ ID NO: 3 or a functionally active fragment thereof, or complementary sequences.

As used herein, “percent (%) sequence identity” with respect to a specified subject sequence, or a specified portion thereof, is defined as the percentage of nucleotides or amino acids in the candidate derivative sequence identical with the nucleotides or amino acids in the subject sequence (or specified portion thereof), after aligning the sequences and introducing gaps, if necessary to achieve the maximum percent sequence identity, as generated by the program WU-BLAST-2.0a19 (Altschul et al., J. Mol. Biol. 215:403-410, 1997) with search parameters set to default values. The HSP S and HSP S2 parameters are dynamic values and are established by the program itself depending upon the composition of the particular sequence and composition of the particular database against which the sequence of interest is being searched. A “% identity value” is determined by the number of matching identical nucleotides or amino acids divided by the sequence length for which the percent identity is being reported. “Percent (%) amino acid sequence similarity” is determined by doing the same calculation as for determining % amino acid sequence identity, but including conservative amino acid substitutions in addition to identical amino acids in the computation. A conservative amino acid substitution is one in which an amino acid is substituted for another amino acid having similar properties such that the folding or activity of the protein is not significantly affected. Aromatic amino acids that can be substituted for each other are phenylalanine, tryptophan, and tyrosine; interchangeable hydrophobic amino acids are leucine, isoleucine, methionine, and valine; interchangeable polar amino acids are glutamine and asparagine; interchangeable basic amino acids are arginine, lysine and histidine; interchangeable acidic amino acids are aspartic acid and glutamic acid; and interchangeable small amino acids are alanine, serine, threonine, cysteine and glycine.

Derivative nucleic acid molecules of the subject nucleic acid molecules include sequences that hybridize to the nucleic acid sequence of SEQ ID NO: 5, SEQ ID NO: 1 or SEQ ID NO: 3. The stringency of hybridization can be controlled by temperature, ionic strength, pH, and the presence of denaturing agents such as formamide during hybridization and washing. Conditions routinely used are well known (see, e.g., Current Protocol in Molecular Biology, Vol. 1, Chap. 2.10, John Wiley & Sons, Publishers, 1994; Sambrook et al., Molecular Cloning, Cold Spring Harbor, 1989). In some embodiments, a nucleic acid molecule of the invention is capable of hybridizing to a nucleic acid molecule containing the nucleotide sequence of SEQ ID NO: 5, SEQ ID NO: 1 or SEQ ID NO: 3 under stringent hybridization conditions that are: prehybridization of filters containing nucleic acid for 8 hours to overnight at 65° C. in a solution comprising 6× single strength citrate (SSC) (1×SSC is 0.15 M NaCl, 0.015 M Na citrate; pH 7.0), 5×Denhardt's solution, 0.05% sodium pyrophosphate and 100 μg/ml herring sperm DNA; hybridization for 18-20 hours at 65° C. in a solution containing 6×SSC, 1×Denhardt's solution, 100 μg/ml yeast tRNA and 0.05% sodium pyrophosphate; and washing of filters at 65° C. for 1 h in a solution containing 0.1× SSC and 0.1% SDS (sodium dodecyl sulfate). In other embodiments, moderately stringent hybridization conditions are used that are: pretreatment of filters containing nucleic acid for 6 h at 40° C. in a solution containing 35% formamide, 5×SSC, 50 mM Tris-HCl (pH 7.5), 5 mM EDTA, 0.1% PVP, 0.1% Ficoll, 1% BSA, and 500 μg/ml denatured salmon sperm DNA; hybridization for 18-20 h at 40° C. in a solution containing 35% formamide, 5×SSC, 50 mM Tris-HCl (pH 7.5), 5 mM EDTA, 0.02% PVP, 0.02% Ficoll, 0.2% BSA, 100 μg/ml salmon sperm DNA, and 10% (wt/vol) dextran sulfate; followed by washing twice for 1 hour at 55° C. in a solution containing 2×SSC and 0.1% SDS. Alternatively, low stringency conditions can be used that comprise: incubation for 8 hours to overnight at 37° C. in a solution comprising 20% formamide, 5×SSC, 50 mM sodium phosphate (pH 7.6), 5× Denhardt's solution, 10% dextran sulfate, and 20 μg/ml denatured sheared salmon sperm DNA; hybridization in the same buffer for 18 to 20 hours; and washing of filters in 1×SSC at about 37° C. for 1 hour.

As a result of the degeneracy of the genetic code, a number of polynucleotide sequences encoding an AFB4, AFB5 or SGT1b polypeptides can be produced. For example, codons may be selected to increase the rate at which expression of the polypeptide occurs in a particular host species, in accordance with the optimum codon usage dictated by the particular host organism (see, e.g., Nakamura et al. N A R 27: 292, 1999). Such sequence variants may be used in the methods of this invention.

The methods of the invention may use orthologs of the Arabidopsis AFB4, AFB5 or SGT1b. Methods of identifying the orthologs in other plant species are known in the art. Normally, orthologs in different species retain the same function, due to presence of one or more protein motifs and/or 3-dimensional structures. In evolution, when a gene duplication event follows speculation, a single gene in one species, such as Arabidopsis, may correspond to multiple genes (paralogs) in another. As used herein, the term “orthologs” encompasses paralogs. When sequence data is available for a particular plant species, orthologs are generally identified by sequence homology analysis, such as BLAST analysis, usually using protein bait sequences. Sequences are assigned as a potential ortholog if the best hit sequence from the forward BLAST result retrieves the original query sequence in the reverse BLAST (Huynen M A and Bork P, Proc Natl Acad Sci, 95:5849-5856, 1998; Huynen M A et al., Genome Research, 10:1204-1210, 2000). Programs for multiple sequence alignment, such as CLUSTAL (Thompson J D et al, Nucleic Acids Res 22:4673-4680, 1994) may be used to highlight conserved regions and/or residues of orthologous proteins and to generate phylogenetic trees. In a phylogenetic tree representing multiple homologous sequences from diverse species (e.g., retrieved through BLAST analysis), orthologous sequences from two species generally appear closest on the tree with respect to all other sequences from these two species. Structural threading or other analysis of protein folding (e.g., using software by ProCeryon, Biosciences, Salzburg, Austria) may also identify potential orthologs. Nucleic acid hybridization methods may also be used to find orthologous genes and are preferred when sequence data are not available. Degenerate PCR and screening of cDNA or genomic DNA libraries are common methods for finding related gene sequences and are well known in the art (see, e.g., Sambrook et al., Molecular Cloning, Cold Spring Harbor, 1989; Dieffenbach and Dveksler, PCR Methods and Applications 3: S2-S7, 1993). For instance, methods for generating a cDNA library from the plant species of interest and probing the library with partially homologous gene probes are described in Sambrook et al., (Molecular Cloning, Cold Spring Harbor, 1989). A highly conserved portion of the Arabidopsis AFB4, AFB5 or SGT1b coding sequences may be used as probes. AFB4, AFB5 or SGT1b ortholog nucleic acids may hybridize to the nucleic acid of SEQ ID NO: 5, SEQ ID NO: 1 or SEQ ID NO: 3 under high, moderate, or low stringency conditions. After amplification or isolation of a segment of a putative ortholog, that segment may be cloned and sequenced by standard techniques and utilized as a probe to isolate a complete cDNA or genomic clone. Alternatively, it is possible to initiate an EST project to generate a database of sequence information for the plant species of interest. In another approach, antibodies that specifically bind known AFB4, AFB5 or SGT1b polypeptides are used for ortholog isolation (see, e.g., Harlow & Lane, Cold Spring Harbor Laboratory, NY, 1988, 1999). Western blot analysis can determine that AFB4, AFB5 or SGT1b orthologs (i.e., an orthologous protein) is present in a crude extract of a particular plant species. When reactivity is observed, the sequence encoding the candidate ortholog may be isolated by screening expression libraries representing the particular plant species. Expression libraries can be constructed in a variety of commercially available vectors, including lambda gt11, as described in Sambrook, et al., (Molecular Cloning, Cold Spring Harbor, 1989). Once the candidate ortholog(s) are identified by any of these means, candidate orthologous sequence are used as bait (the “query”) for the reverse BLAST against sequences from Arabidopsis or other species in which AFB4, AFB5 or SGT1b nucleic acids and/or polypeptide sequences have been identified.

AFB4, AFB5 or SGT1b nucleic acids and polypeptides may be obtained using any available method. For instance, techniques for isolating cDNA or genomic DNA sequences of interest by screening DNA libraries or by using polymerase chain reaction (PCR), as previously described, are well known in the art. Alternatively, nucleic acid sequence may be synthesized. Any known method, such as site directed mutagenesis (Kunkel et al., Methods in Enzymology 204: 125-139, 1991), may be used to introduce desired changes into a cloned nucleic acid.

In general, the methods of the invention involve incorporating the desired form of the AFB4, AFB5 or SGT1b nucleic acids into a plant expression vector for transformation of in plant cells, and the AFB4, AFB5 or SGT1b polypeptides are expressed in the host plant.

An “isolated” AFB4, AFB5 or SGT1b nucleic acid molecule or protein is other than in the form or setting in which it is found in nature. An “isolated” polynucleotide is and separated from least one contaminant nucleic acid molecule with which it is ordinarily associated in the natural source of the AFB4, AFB5 or SGT1b nucleic acid. However, an isolated AFB4, AFB5 or SGT1b nucleic acid molecule includes AFB4, AFB5 or SGT1b nucleic acid molecules contained in cells that ordinarily express AFB4, AFB5 or SGT1b where, for example, the nucleic acid molecule is in a chromosomal location different from that of natural cells.

Chemical Structures of Picolinate Auxins, and Identification of the Binding Site for Picolinate Auxins on AFB4 or AFB5

The binding site of picolinate auxins on AFB4 or AFB5 may be identified by dissecting functional domains of the protein. Assays described in Dharmasiri et al. (2005 Nature 435:441-445) and Kepinski and Leyser (Nature, 435:446-451, 2005) have demonstrated that the natural auxin IAA binds directly to TIR1. Similar assays will be used to demonstrate that picolinate auxins bind to AFB4 or AFB5. Briefly, fusion proteins of AFB4 or AFB5 and the myc epitope will be made and tested for ability to interact with an IAA protein in a picolinate auxin-dependent manner. The interaction of AFB4 or AFB5 and AUX/IAA proteins may be tested in vitro by “pull down” experiments. Arabidopsis has approximately 25 AUX/IAA proteins and AFB5 may interact with some or all of them. AUX2 and AUX3 are commonly used in “pull down” experiments with TIR1 and can be used in experiments with AFB4 or AFB5. In “pull down” experiments, antibodies to one protein are used to immunoprecipitate a protein complex. The precipitated proteins are separated by electrophoresis and other proteins in the complex are detected by immunoblot analysis. The “pull down” experiments may be performed with the cloned proteins and antiserum specific for them used for immunoprecipitation and immunodetection. Alternatively epitopes recognized by commercially available antiserum may be fused to the proteins and a commercially available antisera used. For example, sequences encoding the myc epitope (EQKLISEEDL) (SEQ ID NO: 13) may be fused with sequences encoding AFB4 or AFB5 such that the myc epitope is fused at the N or preferably at the C terminus of the AFB4 or AFB5 protein forming AFB4-myc or AFB5-myc fusion proteins, respectively. Similarly, sequences encoding the glutathione S transferase (GST) protein may be fused to sequences encoding the AUX2 protein such that the GST protein is fused at the C terminus of the AUX2 protein. The AFB4-myc or AFB5-myc fusion protein is made by transcribing and translating the gene in a non-plant system. Transcripts encoding the AFB4-myc or AFB5-myc fusion protein may be translated in a cell free system, such as the wheat germ or reticulate lysate systems or the AFB5-myc gene may be transformed into E. coli, yeast, insect cells or some other appropriate host and the fusion protein purified from cell extracts. The AUX2-GST fusion protein may be purified similarly. The interaction of the AFB4-myc or AFB5-myc protein with AUX2-GST fusion may be tested by incubating the two proteins in the presence and absence of picolinate auxins such as DAS534, immunoprecipitating protein complexes with the commercially available myc antiserum, resuspending the immunoprecipitate and separating the proteins by electrophoresis. Immunoblot analysis using anti-GST antiserum will determine how much of the AUX2-GST fusion protein is interacting with the AFB4-myc or AFB5-myc protein. Detecting more AUX2-GST protein when DAS534 is included in the assay will indicate that DAS534 stimulates the interaction of AFB4 or AFB5 and AUX2. As a control, similar experiments can be done with TIR1-myc fusion proteins. The TIR1/AUX2 interaction is stimulated weakly or not at all by picolinate auxins.

To determine which portion of the AFB4 or AFB5 protein interacts with picolinate auxins, fusion proteins composed of portions of AFB5 and TIR1 can be constructed. For example the N-terminal portion of TIR1 encoding the F-box can be attached to the C terminal portion of AFB5 encoding the leucine rich repeat (LRR) domain. If the fusion protein should interact less strongly with AUX2 in the presence of picolinate auxins, than the wild-type protein, it may indicate that picolinate auxins interact with the AFB4 or AFB5 in the F-box portion of the protein. Similarly, the N-terminal, F-box encoding portion of AFB4 or AFB5 is fused with the C-terminal, LRR domain encoding portion of TIR1 and be used in “pull down” experiments. In this case, if the fusion protein interacts with AUX2 more strongly than the wild-type TIR1 protein, it will indicate that picolinate auxins interact with F-box proteins through the F-box domain. Using chimeric AFB4-TIR1 or AFB5-TIR1 fusion proteins similar to the ones described above, the picolinate auxin binding site on AFB5 may be determined.

The herbicide DAS534 (compound 173 in PCT publication WO 2003011853), 4-amino-3-chloro-5-fluoro-6-(4-chlorophenyl)pyridine-2-carboxylic acid, has the following chemical structure:

“Picolinate auxins” contain the core structure, 3-chloro-2-picolinic acid:

“Aryloxyalkanoate auxins” contain the core structures, 4-chlorophenoxyacetic acid or 2-(4-chlorophenoxy)-propionic acid or 5-chloro-2-pyridinyloxyacetic acid:

Functional Assay of AFB5 to Identify Other Herbicidal Compounds

The “pull down” experiments described above can be used to identify other compounds that stimulate interaction between AFB5 and AUX/IAA proteins. In these experiments, test compounds would be added to the mixture of AFB4 or AFB5 and AUX2. Antiserum to the AFB4 or AFB5 protein would be used to immunoprecipitate protein complexes. These complexes would be resuspended and the proteins separated by electrophoresis. Immunodetection using antiserum to the AUX2 protein would be used to quantitate the amount of AUX2 protein interacting with AFB4 or AFB5. Compounds that stimulate the interaction would be evaluated for auxinic activity on whole plants. Although any compounds could be screened in this assay, the preferred embodiment would be compounds that contain a picolinate or similar moiety.

Ligand-Binding Assay of AFB5 to Identify Herbicidal Compounds

Binding of compounds to AFB4 or AFB5 can be detected by ligand displacement techniques wherein a picolinate auxin is labeled with a radioisotope such as tritium or with a tag such as biotin or with a fluorescent moiety. The amount of binding of the picolinate auxin to AFB4 or AFB5 can be detected by separation of the protein from the medium by immunoprecipitation or other protein capture methods. Alternatively alterations in a fluorescent signal from a fluorescence-tagged picolinate on binding to AFB4 or AFB5 can provide a signal for ligand-binding. These detection methods for ligand-binding provide convenient and high-throughput techniques for screening compounds to identify those that inhibit binding of the tagged picolinate auxin to AFB4 or AFB5. These experiments may be facilitated by heterologous expression of AFB4 or AFB5 proteins in a suitable host system such as E. coli or Saccharomyces cerevisiae or via baculovirus expression in insect cell cultures.

Combining In Vitro Assays to Identify Potent Broad Spectrum Auxins

There is redundancy in auxin receptors (AFBs) at the gene and protein level. Current herbicidal auxins interact only with a subset of these proteins for example 2,4-D interacts with TIR1 and close homologs whereas picloram preferentially interacts with AFB4 or AFB5. Consequently a preferred embodiment is to select compounds for optimization by identifying those that interact with TIR1, AFB4 and AFB5 in biochemical ligand-binding or functional assays. This will identify compounds such as DAS534 that interact strongly with both classes of receptor and thus have the potential for increased potency and/or broader spectrum.

Co-Crystals of Picolinates and AFB4 or AFB5

Purification of AFB4 or AFB5, especially from heterologous expression systems, allows the protein to be crystallized either on its own or within the E3 protein ligase complex with which it associates. See for example the crystallization of the SCF complex described in Zheng et al. (Nature 416:703-708, 2002). The protein structure can then be determined by X-ray crystallography. Crystallization can be done in the presence and absence of a picolinate auxin ligand by co-crystallography or by ligand-soaking into preformed crystals. This enables the binding region involved in the protein-ligand interaction to be discerned. The features of this molecular interaction can then be used for the design and synthesis of novel compounds that can occupy the site to effect herbicidal activity. Alternatively, the binding pocket can be used as a template to computationally screen and identify compounds with the potential to bind to the site. These can then be experimentally verified as binding to the protein by further in vitro or in vivo assays.

Generation of Genetically Modified Plants with a Picolinate Auxin-Resistant Phenotype

AFB4, AFB5 or SGT1b nucleic acids and polypeptides may be used in the generation of genetically modified plants having an auxin-resistant phenotype. As used herein, an “auxin resistant phenotype” may refer to resistance to any naturally occurring or synthetic molecule that elicits auxinic herbicidal symptoms when applied to plants. A preferred embodiment is for resistance to compounds containing a picolinate or similar moiety.

The methods described herein are generally applicable to all plants. Although EMS mutagenesis and gene identification was carried out in Arabidopsis, the AFB4, AFB5 and SGT1b genes (or an ortholog, variant or fragment thereof) may be expressed in any type of plant. In a preferred embodiment, the invention is directed to plants known as row crops. Examples of row crop species include soybean (Glycine max), rapeseed and canola (including Brassica napus, B. campestris), sunflower (Helianthus annuus), cotton (Gossypium hirsutum), corn (Zea mays), cocoa (Theobroma cacao), safflower (Carthamus tinctorius), oil palm (Elaeis guineensis), coconut palm (Cocos nucifera), flax (Linum usitatissimum), castor (Ricinus communis), sorghum (Sorghum bicolor) and peanut (Arachis hypogaea). The invention may also be directed to fruit- and vegetable-bearing plants, grain-producing plants, nut-producing plants, rapid cycling Brassica species, alfalfa (Medicago sativa), tobacco (Nicotiana spp.), turfgrass (Poaceae family), clover (Trifolium spp.) and other forage crops.

The auxin-resistant phenotype may be generated by expressing AFB4, AFB5 or SGT1b gene in antisense or hairpin RNAs, by over-expressing AFB4, AFB5 or SGT1b and causing co-suppression, or by developing a dominant negative protein that inhibits the function of the native protein. Antisense RNAs are formed when the coding sequences of a protein encoding nucleic acid are expressed in the opposite orientation. These RNAs can hybridize with mRNAs transcribed from endogenous genes and inhibit their expression. Hairpin RNAs are formed when all or a portion of the coding sequences of a gene are cloned in the sense and antisense orientation in the same transcription unit. Upon transcription of these constructs, the transcript forms a hairpin structure and triggers a transcript degradation pathway that targets both the hairpin-encoding gene and the endogenous gene. This degradation pathway can effectively silence endogenous gene expression (Smith et al. Nature 407:319-320, 2000). Co-suppression is caused by the over-expression of a transgene; high level of expression can cause the degradation of transcripts from the native gene (Que et al. Plant Cell 9:1357-1368, 1997). Dominant negative mutants may be generated by over-expressing a mutant form of the protein (Pontier et al., Plant Cell 27:529-538, 2001). Since AFB4, AFB5 and SGT1b interact with components of the SCF complex, over-expression of mutant forms of the proteins may disrupt the auxin-responsive SCF complex, prevent auxin signaling and cause the transgenic plants to be auxin resistant.

The skilled artisan will recognize that a wide variety of transformation techniques exist in the art, and new techniques are continually becoming available. Any technique that is suitable for the target host plant can be employed within the scope of the present invention. For example, the constructs can be introduced in a variety of forms including, but not limited to as a strand of DNA, in a plasmid, or in an artificial chromosome. The introduction of the constructs into the target plant cells can be accomplished by a variety of techniques, including, but not limited to Agrobacterium-mediated transformation, electroporation, microinjection, microprojectile bombardment calcium-phosphate-DNA co-precipitation or liposome-mediated transformation of a heterologous nucleic acid. The transformation of the plant is preferably permanent, i.e. by integration of the introduced expression constructs into the host plant genome, so that the introduced constructs are passed onto successive plant generations. Depending upon the intended use, a heterologous nucleic acid construct comprising an AFB4, AFB5 or SGT1b polynucleotide may encode the entire protein or a biologically active portion thereof.

In one embodiment, binary Ti-based vector systems may be used to transfer polynucleotides. Standard Agrobacterium binary vectors are known to those of skill in the art, and many are commercially available (e.g., pBI121 Clontech Laboratories, Palo Alto, Calif.). A construct or vector may include a plant promoter to express the nucleic acid molecule of choice. In a preferred embodiment, the promoter is a plant promoter.

The optimal procedure for transformation of plants with Agrobacterium vectors will vary with the type of plant being transformed. Exemplary methods for Agrobacterium-mediated transformation include transformation of explants of hypocotyl, shoot tip, stem or leaf tissue, derived from sterile seedlings and/or plantlets. Such transformed plants may be reproduced sexually, or by cell or tissue culture. Agrobacterium transformation has been previously described for a large number of different types of plants and methods for such transformation may be found in the scientific literature. Of particular relevance are methods to transform commercially important crops, such as rapeseed (De Block et al., Plant Physiol 91: 694-701, 1989), sunflower (Everett et al., Bio/Technology 5: 1201-1204, 1987), and soybean (Christou et al., Proc Natl Acad Sci USA 86: 7500-7504, 1989; Kline et al., Nature 327: 70-73, 1987).

Expression (including transcription and translation) of AFB4, AFB5 or SGT1b may be regulated with respect to the level of expression, the tissue type(s) where expression takes place and/or developmental stage of expression. A number of heterologous regulatory sequences (e.g., promoters and enhancers) are available for controlling the expression of an AFB4, AFB5 or SGT1b nucleic acid. These include constitutive, inducible and regulatable promoters, as well as promoters and enhancers that control expression in a tissue- or temporal-specific manner. Exemplary constitutive promoters include, but are not limited to, the raspberry E4 promoter (U.S. Pat. Nos. 5,783,393 and 5,783,394), the nopaline synthase (NOS) promoter (Ebert et al., Proc. Natl. Acad. Sci. (U.S.A.) 84:5745-5749, 1987), the octopine synthase (OCS) promoter (which is carried on tumor-inducing plasmids of Agrobacterium tumefaciens), the caulimovirus promoters such as the cauliflower mosaic virus (CaMV) 19S promoter (Lawton et al., Plant Mol. Biol. 9:315-324, 1987) and the CaMV ³⁵S promoter (Odell et al., Nature 313:810-812, 1985 and Jones et al, Transgenic Res. 1(6):285-297, 1992), the melon actin promoter (published PCT application WO 00/56863), the figwort mosaic virus 35S-promoter (U.S. Pat. No. 5,378,619), the light-inducible promoter from the small subunit of ribulose-1,5-bis-phosphate carboxylase (ssRUBISCO), the Adh promoter (Walker et al., Proc. Natl. Acad. Sci. (U.S.A.) 84:6624-6628, 1987), the sucrose synthase promoter (Yang et al., Proc. Natl. Acad. Sci. (U.S.A.) 87:4144-4148, 1990), the R gene complex promoter (Chandler et al., The Plant Cell 1:1175-1183, 1989), the chlorophyll a/b binding protein gene promoter the CsVMV promoter (Verdaguer et al., Plant Mol Biol 37: 1055-1067, 1998), these promoters have been used to create DNA constructs that have been expressed in plants; see, e.g., PCT publication WO 84/02913. Exemplary tissue-specific promoters include the tomato E4 and E8 promoters (U.S. Pat. No. 5,859,330) and the tomato 2AII gene promoter (Van Haaren et al., Plant Mol Biol 21: 625-640, 1993).

In yet another aspect, in some cases it may be desirable to inhibit the expression of endogenous AFB4, AFB5 or SGT1b in a host cell. Exemplary methods for practicing this aspect of the invention include, but are not limited to antisense suppression (Smith, et al., Mol Gen Genet. 224: 477-481, 1988; van der Krol et al., BioTechniques 6: 958-976, 1988); co-suppression (Napoli, et al., Plant Cell 2: 279-289, 1990); ribozymes (PCT Publication WO 97/10328); and combinations of sense and antisense (Waterhouse, et al., Proc Natl Acad Sci USA 95: 13959-13964, 1998). Methods for the suppression of endogenous sequences in a host cell typically employ the transcription or transcription and translation of at least a portion of the sequence to be suppressed. Such sequences may be homologous to coding as well as non-coding regions of the endogenous sequence. Antisense inhibition may use the entire cDNA sequence (Sheehy et al., Proc Natl Acad Sci USA 85: 8805-8809, 1988), a partial cDNA sequence including fragments of 5′ coding sequence, (Cannon et al., Plant Mol Biol 15: 39-47, 1990), or 3′ non-coding sequences (Ch'ng et al., Proc Natl Acad Sci USA 86: 10006-10010, 1989). Cosuppression techniques may use the entire cDNA sequence (Napoli et al., Plant Cell 2: 279-289, 1990; van der Krol et al., Plant Cell 2: 291-299, 1990), or a partial cDNA sequence (Smith et al., Mol Gen Genet. 224: 477-481, 1990).

AFB4, AFB5 or SGT1b activity can be decreased by decreasing in the expression levels of AFB4, AFB5 or SGT1b and/or decreasing the activity of AFB4, AFB5, or SGT1b collectively these are referred to as “gene down-regulation mechanisms”. Decreased activity of AFB4, AFB5 or SGT1b can be obtained, for example, by decreasing expression of the AFB4, AFB5 or SGT1b polypeptides, or variants or fragments thereof. For example, a nucleotide sequence may be introduced into a cell or plant that encodes a protein that leads to decreased AFB4, AFB5, or SGT1b expression, such as a protein that interferes with the AFB4, AFB5 or SGT1b promoter. Alternatively, a non-protein-encoding nucleotide sequence that decreases (inhibits) expression of AFB4, AFB5 or SGT1b, or variant or fragment thereof, may be introduced into a cell or plant. The inhibitory nucleotide sequence may hybridize to a nucleotide sequence encoding the AFB4, AFB5 or SGT1b polypeptide, or variant or fragment thereof. Inhibitory nucleotide sequences include, but are not limited to, an antisense nucleotide sequence, a siRNA or a ribozyme. A chemical compound that is capable of decreasing AFB4, AFB5 or SGT1b expression may be introduced into the cell or plant.

In one embodiment, inhibition of AFB4, AFB5, or SGT1b activity is obtained through the use of antisense technology. Antisense oligonucleotides as a method of suppression are well known in the art. Although the exact mechanism by which antisense RNA molecules interfere with gene expression has not been elucidated, it is believed that antisense RNA molecules bind to the endogenous mRNA molecules and thereby inhibit translation of the endogenous mRNA.

Herein is provided a means to alter levels of expression of AFB4, AFB5, or SGT1b by the use of a synthetic antisense oligonucleotide compound that inhibits translation of mRNA encoding AFB4, AFB5, or SGT1b. Synthetic antisense oligonucleotides, or other antisense chemical structures designed to recognize and selectively bind to mRNA, are constructed to be complementary to portions of the nucleotide sequence shown in SEQ ID NO: 1, SEQ ID NO: 3 and SEQ ID NO: 5. In addition, the antisense oligonucleotide may be designed for administration only to certain selected cell populations by targeting the antisense oligonucleotide to be recognized by specific cellular uptake mechanisms that bind and take up the antisense oligonucleotide only within certain selected cell populations. For example, the antisense oligonucleotide may be designed to bind to transporter found only in a certain cell type. The antisense oligonucleotide may be designed to inactivate the AFB4, AFB5, or SGT1b mRNA by (1) binding to the AFB4, AFB5, or SGT1b mRNA and thus inducing degradation of the mRNA by intrinsic cellular mechanisms such as RNase I digestion, (2) by inhibiting translation of the mRNA target by interfering with the binding of translation-regulating factors or of ribosomes, or (3) by inclusion of other chemical structures, such as ribozyme sequences or reactive chemical groups, which either degrade or chemically modify the target mRNA. Synthetic antisense oligonucleotide drugs have been shown to be capable of the properties described above when directed against mRNA targets (Cohen, Trends Pharmacol. Sci. 10:435-437, 1989). In addition, coupling of ribozymes to antisense oligonucleotides is a promising strategy for inactivating target mRNA (Sarver et al., Science 247:1222-1225, 1990). In this manner, an antisense oligonucleotide directed to AFB4, AFB5, or SGT1b can be used to reduce AFB4, AFB5, or SGT1b expression in particular target cells.

The introduced sequence need not be the full-length AFB4, AFB5, or SGT1b cDNA (SEQ ID NO: 5, SEQ ID NO: 1 and SEQ ID NO: 3, respectively) and need not be exactly homologous to the equivalent sequence found in the cell type to be transformed. The sequence may comprise a flanking region of AFB4, AFB5, or SGT1b. Flanking regions of AFB4, AFB5, or SGT1b in any target plant may be obtained using the sequences provided herein.

In one embodiment, portions or fragments of the AFB4, AFB5, or SGT1b cDNA (SEQ ID NO: 5, SEQ ID NO: 1 and SEQ ID NO: 3, respectively) could be used to knock out expression of the AFB4, AFB5, or SGT1b gene. Generally, however, where the introduced sequence is of shorter length, a higher degree of identity to the native AFB4, AFB5, or SGT1b sequence will be needed for effective antisense suppression. In other embodiments, the introduced antisense sequence in the vector may be at least 15 nucleotides in length, and improved antisense suppression typically will be observed as the length of the antisense sequence increases. In yet other embodiments, the length of the antisense sequence in the vector advantageously may be greater than 100 nucleotides, and can be up to about the full length of the AFB4, AFB5, or SGT1b cDNA or gene. In another embodiment, for suppression of the AFB4, AFB5, or SGT1b gene itself, transcription of an antisense construct results in the production of RNA molecules that are the reverse complement of mRNA molecules transcribed from the endogenous AFB4, AFB5, or SGT1b gene in the cell.

In one embodiment, the oligonucleotide is at least about 10 nucleotides in length, such as, greater than about 20 bases in length, greater than about 30 bases in length, greater than about 40 bases in length, greater than about 50 bases in length, greater than about 100 bases in length, greater than about 200 bases in length or greater than about 300 bases in length. In one embodiment, the oligonucleotide has a ribozyme activity.

In one specific, non-limiting embodiment, a nucleotide sequence from an AFB4, AFB5, or SGT1b encoding sequence is arranged in reverse orientation relative to the promoter sequence in the transformation vector.

The synthesis of effective anti-sense inhibitors is known. Synthetic antisense oligonucleotides may be produced, for example, in a commercially available oligonucleotide synthesizer. Numerous approaches have been previously described and generally involve altering the backbone of the polynucleotide to increase its stability in vivo. Exemplary oligonucleotides and methods of synthesis are described in U.S. Pat. Nos. 5,661,134; 5,635,488; and 5,599,797 (phosphorothioate linkages), U.S. Pat. Nos. 5,587,469 and 5,459,255 (N-2 substituted purines), U.S. Pat. No. 5,539,083 (peptide nucleic acids) and U.S. Pat. Nos. 5,629,152; 5,623,070; and 5,610,289 (miscellaneous approaches).

In another embodiment, suppression of endogenous AFB4, AFB5, or SGT1b expression can be achieved using ribozymes. Ribozymes are synthetic RNA molecules that possess highly specific endoribonuclease activity. The production and use of ribozymes are disclosed in U.S. Pat. No. 4,987,071 to Cech and U.S. Pat. No. 5,543,508 to Haselhoff. In one embodiment, the inclusion of ribozyme sequences within antisense RNAs may be used to confer RNA cleaving activity on the antisense RNA, such that endogenous mRNA molecules that bind to the antisense RNA are cleaved, which in turn leads to an enhanced antisense inhibition of endogenous gene expression. In yet another embodiment, dominant negative mutant forms of AFB4, AFB5, or SGT1b may be used to block endogenous AFB4, AFB5, or SGT1b activity.

Decreased activity of AFB4, AFB5, or SGT1b may also be obtained by decreasing the activity of the AFB4, AFB5, or SGT1b protein with or without decreasing expression levels. For example, a nucleotide sequence encoding a protein that inhibits or inactivates AFB4, AFB5, or SGT1b activity may be introduced into the cell or plant.

In one embodiment, a mutant or variant of AFB4, AFB5, or SGT1b is introduced or expressed in a cell. The variant of AFB4, AFB5, or SGT1b optionally may have increased expression or decreased expression. Cells may have AFB4, AFB5, or SGT1b null mutations, AFB4, AFB5, or SGT1b missense mutations, AFB4, AFB5, or SGT1b truncation mutations, or inactivation of AFB4, AFB5, or SGT1b. In one embodiment, a mutant AFB4, AFB5, or SGT1b is expressed in a cell but is incapable of localizing to the correct subcellular location. In another embodiment, a mutant AFB4, AFB5, or SGT1b is incapable of binding to one or more of its intracellular binding partners. In yet another embodiment, a mutation in the upstream regulatory region of the AFB4, AFB5, or SGT1b gene abrogates the expression of the protein. In another embodiment, a mutant AFB4, AFB5, or SGT1b is incapable of forming an active SCF complex.

It is possible that mutations in the AFB4, AFB5, or SGT1b gene are not included in the cDNA but rather are located in other regions of the AFB4, AFB5, or SGT1b gene. Mutations located outside of the ORF that encode the AFB4, AFB5, or SGT1b protein are not likely to affect the functional activity of the proteins, but rather are likely to result in altered levels of the proteins in the cell. For example, mutations in the promoter region of the AFB4, AFB5, or SGT1b gene may prevent transcription of the gene and therefore lead to the complete absence of the AFB4, AFB5, or SGT1b protein, or absence of certain transcripts of the protein, in the cell.

Additionally, mutations within introns in the genomic sequence may also prevent expression of the AFB4, AFB5, or SGT1b protein. Following transcription of a gene containing introns, the intron sequences are removed from the RNA molecule, in a process termed splicing, prior to translation of the RNA molecule that results in production of the encoded protein. When the RNA molecule is spliced to remove the introns, the cellular enzymes that perform the splicing function recognize sequences around the intron/exon border and in this manner recognize the appropriate splice sites. If a mutation exists within the sequence of the intron near and exon/intron junction, the enzymes may not recognize the junction and may fail to remove the intron. If this occurs, the encoded protein will likely be defective. Thus, mutations inside the intron sequences within the AFB4, AFB5, or SGT1b gene (termed “splice site mutations”) may also lead to defects in transporter activity. However, knowledge of the exon structure and intronic splice site sequences of the AFB4, AFB5, or SGT1b gene is required to define the molecular basis of these abnormalities. The provision herein of AFB4, AFB5, or SGT1b cDNA sequences enables the cloning of the entire AFB4, AFB5, or SGT1b gene (including the promoter and other regulatory regions and the intron sequences) from any target plant, and the determination of its nucleotide sequence.

Standard molecular and genetic tests may be performed to further analyze the association between a gene and an observed phenotype. Exemplary techniques are described below.

1. DNA/RNA Analysis

The stage- and tissue-specific gene expression patterns in mutant versus wild-type lines may be determined, for instance, by in situ hybridization. Analysis of the methylation status of the gene, especially flanking regulatory regions, may be performed. Other suitable techniques include overexpression, ectopic expression, expression in other plant species and gene knock-out (reverse genetics, targeted knock-out, viral induced gene silencing [VIGS, see Baulcombe D, Current Opinion in Plant Biology 2: 109-113, 1999]).

In one preferred application, expression profiling (generally by microarray analysis) is used to simultaneously measure differences or induced changes in the expression of many different genes. Techniques for microarray analysis are well known in the art (Schena et al., Science 270:467-470, 1995; Baldwin et al., Curr Opin Plant Biol. 2(2):96-103, 1999; Dangond, Physiol Genomics 2:53-58, 2000; van Hal et al., J Biotechnol 78:271-280, 2000; Richmond & Somerville, Curr Opin Plant Biol 3:108-116, 2000). Expression profiling of individual tagged lines may be performed. Such analysis can identify other genes that are coordinately regulated as a consequence of the over-expression of the gene of interest, which may help to place an unknown gene in a particular pathway.

2. Gene Product Analysis

Analysis of gene products may include recombinant protein expression, antisera production, immunolocalization, biochemical assays for catalytic or other activity, analysis of phosphorylation status, and analysis of interaction with other proteins via yeast two-hybrid assays.

3. Pathway Analysis

Pathway analysis may include placing a gene or gene product within a particular biochemical, metabolic or signaling pathway based on its mis-expression phenotype or by sequence homology with related genes. Alternatively, analysis may comprise genetic crosses with wild-type lines and other mutant lines (creating double mutants) to order the gene in a pathway, or determining the effect of a mutation on expression of downstream “reporter” genes in a pathway.

Generation of Mutated Plants with a Picolinate-Resistance Phenotype

The invention further provides a method of identifying plants that have mutations in endogenous AFB4, AFB5 or SGT1b that confer auxin resistance. In one method, called “TILLING” (for Targeting Induced Local Lesions IN Genomes), mutations are induced in the seed of a plant of interest, for example, using EMS treatment. The resulting plants are grown and self-fertilized, and the progeny are used to prepare DNA samples. Gene specific PCR is used to identify whether a mutated plant has an AFB4, AFB5 or SGT1b mutation. Plants having AFB4, AFB5 or SGT1b mutations may then be tested for auxin resistance, or alternatively, plants may be tested for auxin resistance, and then AFB4, AFB5 or SGT1b-specific PCR is used to determine whether a resistant plant has a mutated AFB4, AFB5 or SGT1b gene. TILLING can identify mutations that may alter the expression of specific genes or the activity of proteins encoded by these genes (see Colbert et al., Plant Physiol 126:480-484, 2001; McCallum et al., Nature Biotechnology 18:455-457, 2000).

In another method, a candidate gene/Quantitative Trait Locus (QTLs) approach can be used in a marker-assisted breeding program to identify alleles of or mutations in AFB4, AFB5 or SGT1b or orthologs that may confer auxin resistance (see Bert et al., Theor Appl Genet., 107(1):181-9, 2003; and Lionneton et al., Genome. 45(6):1203-15, 2002). Thus, in a further aspect of the invention, an AFB4, AFB5 or SGT1b nucleic acid is used to identify whether a plant having an auxin-resistant phenotype has a mutation in endogenous AFB4, AFB5 or SGT1b or has a particular allele that causes auxin resistance.

While the invention has been described with reference to specific methods and embodiments, it will be appreciated that various modifications and changes may be made without departing from the invention. All publications cited herein are expressly incorporated herein by reference for the purpose of describing and disclosing compositions and methodologies that might be used in connection with the invention. All cited patents, patent applications, and sequence information in referenced public databases are also incorporated by reference.

Following are examples that illustrate procedures for practicing embodiments of the invention. These examples should not be construed as limiting. All percentages are by weight and all solvent mixture proportions are by volume unless otherwise noted.

Example 1 Identification and Genetic Characterization of Mutants Resistant to DAS534

To identify mutants resistant to picolinate auxins, EMS-mutagenized M2 seedlings were screened for resistance to DAS534, a 6-phenylpicolinate auxin (Compound 173 in WO 03/011853 A1). The seedlings were grown on agarose medium containing 10 nM DAS534. This concentration was sufficient to produce marked auxinic effects on the seedlings including significant inhibition (60%) of root growth. From a total of 780,100 EMS M2 seedlings, 125 putative resistant mutants were identified by visual inspection. Seeds were recovered from 33 of these plants. Selection of lines for further study was based on the strength of resistance, elimination of potential siblings and the health and fertility of adult plants. To avoid recovering alleles of previously characterized mutants, we preferentially selected lines that showed low or no cross resistance to 0.045 μM 2,4-D. Seven lines resistant to DAS534 had negligible resistance to 2,4-D at this concentration (R009; R024; R045; R127; R051; R107; R118) and were further evaluated. One additional line (R090) showing robust resistance to both DAS534 and 2,4-D was also identified.

The mutants were crossed with wild-type Col-0 plants and the progeny were analyzed for resistance to DAS534. The F₁ plants that resulted from these crosses were all sensitive to DAS534 indicating that the mutations in all of the resistant lines were recessive to the wild type allele. To determine the number of genetic loci identified in this screen, complementation tests were performed by crossing the herbicide-resistant mutants with each other and the known auxin-resistant mutant axr1-3 in a pair-wise fashion. Analysis of the F1 progeny from these crosses by testing for resistance to 10 nM DAS534 revealed that three distinct DAS534-resistant loci were present in the DAS534-resistant mutants. Complementation Group 1 contained the mutants R009, R024, R045 and R127, and complementation Group 2 contained the mutants R051, R107 and R118. All seven selectively-resistant mutant lines were phenotypically normal when grown on agarose medium or in soil and they had normal fertility. The seedlings exhibited normal gravitropism and had normal morphology under etiolating conditions. Group 2 mutants typically exhibited slightly longer roots (−15%) than wild type plants when grown on agarose medium lacking herbicide. Complementation Group 3 contained the mutant R090 which was resistant to both DAS534 and 2,4-D as well as the known auxin-resistant mutant axr1-3. As the mutations in R090 and axr1-3 appeared to be allelic, R090 was not examined further.

Example 2 Chemical Selectivity of Picolinate Auxin Resistant Mutants

The dose responses of root growth of the mutant lines treated with a variety of auxins were measured to define the level and chemical spectrum of resistance in detail. Mutant lines from complementation Groups 1 and 2 had 6 to 8-fold resistance to DAS534 (FIG. 1A). No significant differences in resistance between lines within each complementation group were noted (data not shown). The mutants were very cross-resistant to the picolinate auxin herbicide picloram (FIG. 1B) showing 26 to 60-fold increases in GR₅₀ over that of wild type. Group 2 mutants were slightly more resistant than Group 1 lines. In contrast to the response to DAS534 and picloram, the lines from both complementation groups showed negligible resistance to 2,4-D (FIG. 1C) and a slight increase in sensitivity to IAA (FIG. 1D). The fold resistance levels of the mutants are summarized in Table 1.

Wild-type, Group 1 and Group 2 seedlings growing on 5 nM DAS534 are shown in FIG. 2. At this concentration of DAS534, wild-type plants show slight agravitopism, have elongated hypocotyls and are unable to fully expand their cotyledons (FIG. 2A and FIG. 2F) whereas hypocotyl elongation and cotyledon expansion in the Group 1 mutant R127 and Group 2 mutant R051 are unaffected by DAS534 (FIGS. 2B, 2D, 2G and 2I).

Four additional herbicidal compounds were also tested on the Group 1 line, R127. R127 had 50-fold resistance to the picolinate auxinic herbicide clopyralid. However, it showed no resistance to the benzoate auxin dicamba or to a close analog of the aryloxyacetate auxin, fluoroxypyr or to 1-naphthylacetic acid (1-NAA). It also exhibited no difference in response to the auxin transport inhibitor, napthylphthalamic acid (NPA).

In summary, the Group 1 and Group 2 mutants displayed clear chemical selectivity in their resistance profiles toward the picolinate class of auxin herbicides.

Example 3 Mapping and Identification of DAS534-Resistance Mutations

To identify the genes involved in this chemical selectivity, one mutation from each complementation group (R009 from Group 1 and R051 from Group 2) was genetically mapped. To generate the mapping population, a homozygous mutant M₃ line (from the Col-0 accession) was crossed with a wild-type plant of the Ler accession and the resulting F₁ plants were allowed to self-fertilize and produce F₂ seed. The F₂ seed were germinated on solid medium containing a sublethal concentration of DAS534. Plants resistant to the herbicide were removed from the herbicide-containing medium and allowed to recover on solid medium lacking the herbicide for seven days and then transplanted to soil. When the plants were at the rosette stage, a single leaf was removed and genomic DNA was isolated and used in mapping experiments with molecular genetic markers.

The mutation in R009 was mapped to a 200 kb interval around 105 cM on chromosome 5 between the markers C5_(—)104.6 and C5_(—)111 (FIG. 3). This interval contains 47 genes including At5g49980 annotated by the Arabidopsis Information Resource as a homolog of TIR1. TIR1 is an F-box protein involved in 2,4-D and IAA-mediated SCF function and has recently been shown to be a receptor for auxin (Dharmasiri et al., Nature. 435(7041):441-445, 2005). tir1 mutants are resistant to 2,4-D and IAA (Ruegger et al., Genes Dev 12: 198-207, 1998). Because of this possible linkage to auxin function, At5g49980 was PCR amplified from genomic DNA from the four Group 1 mutant lines and Col-0 plants and compared by DNA sequence analysis. All four DAS534-resistant lines contained G to A mutations in At5g49980 relative to the Col-0 sequence resulting in changes in the encoded polypeptide. The mutations in the deduced amino acid sequences from R024 and R127 introduce stop codons at amino acid residues 220 and 124, respectively. The mutations in R009 and R045 introduce amino acid changes in the encoded polypeptide sequence producing an R to K mutation at position 609 in R009 and a C to Y mutation at position 451 in R045 (FIGS. 4A-4C).

There are six members of the F-box protein subclass that includes TIR1 in the Arabidopsis genome (Gagne et al., Proc Natl Acad Sci USA 99: 11519-11524, 2002). The three closest homologs have been named AFB 1, 2 and 3 (Dharmasiri et al., Dev Cell. 9(1):109-119, 2005). For consistency, we have denoted the two remaining homologs (At4g24390 and At5g49980) as AFB4 and AFB5 respectively. DNA and protein sequences for AFB4 are provided as SEQ ID NOS: 5 and 6, respectively. To confirm that the picolinate auxin resistant phenotypes in Group 1 mutants were caused by the identified lesions in AFB5, the auxin-resistance phenotype was complemented by transformation of the R127 mutant line with a construct containing a wild-type copy of AFB5 driven by the CsVMV promoter (Verdaguer et al., Plant Mol Biol 37: 1055-1067, 1998). T1 plants containing the transgene were selected, allowed to self-fertilize and set seed. T2 seeds that were segregating for the transgene were germinated on medium containing 10 nM DAS534 and the seedlings were scored for sensitivity to the herbicide. Ten independent transformants were identified that restored auxin sensitivity to the mutant (FIG. 2H). Some of these transformants appeared to be hypersensitive to DAS534 because their roots were significantly shorter than those of wild-type plants when grown on herbicide-containing medium. These data confirm that the mutation in AFB5 is indeed responsible for the resistance phenotype in Group 1 mutants. As the DAS534-resistant mutants in complementation Group 1 are resistant to picolinate auxins and not to 2,4-D and all contain lesions in the leucine rich F-box protein AFB5, this protein appears to be specifically involved in mediating the effects of picolinate auxins.

The R051 mutation was mapped to a 100 kb interval on chromosome 4 around 36 cM between markers C4_(—)36 and C4_(—)37 (FIG. 3). This interval contains 17 genes including At4g11260 which encodes the tetratricopeptide-repeat containing protein, SGT1b (SEQ ID NO: 4). A mutation in SGT1b has recently been shown to enhance the level of resistance to 2,4-D in the tir1 mutant background (Gray et al., Plant Cell 15: 1310-1319, 2003). The deletion mutant line edm1 lacks seven genes (At4g11220 through At4g11280) including SGT1b (Tor et al., Plant Cell 14: 993-1003, 2002). We found that this deletion mutant had a similar level of resistance to DAS534 as the Group 2 mutant R051 (FIG. 5A). It was also very cross-resistant to picloram (20-fold, data not shown) similar to the Group 2 mutants. To determine if the DAS534-resistant mutants in complementation Group 2 contained mutations in SGT1b, At4g11260 was PCR amplified from genomic DNA from all three of the mutants. Sequence analysis showed that all three mutants contained lesions producing alterations of the 3′ intron splice sites of At4g11260. Mutants R051 and R118 contained G to A transitions that disrupt the 3′ splice site of intron 7 whereas mutant R107 contained a G to A transition that disrupts the 3′ splice site of intron 6 (FIG. 6).

To confirm that the mutations in At4g11260 were responsible for the DAS534-resistant phenotype, the mutant R051 was transformed with a construct containing the wild type At4g11260 gene driven by the constitutive CsVMV promoter (Verdaguer et al., Plant Mol Biol 37: 1055-1067, 1998). T2 seed were tested for DAS534 sensitivity. Using the same process as was employed for identification of AFB5 transformants, ten independent transformants were identified that were sensitive to DAS534 confirming that the lesions in At4g11260 are responsible for the resistance to DAS534. An example of a R051 line containing the transgene that restores sensitivity to DAS534 is shown in FIG. 2J.

Example 4 Comparison of the Phenotypes of Picolinate Auxin Resistant Mutants with Other Auxin Resistant Mutants

The mutations presently identified in AFB5 and SGT1b conferring picolinate-selective resistance implicate the SCF ubiquitin ligase complex in the molecular mode of action of these herbicides. Several other mutants associated with this complex (e.g., tir1, axr1) or its ubiquitination targets (e.g., axr2) in the auxin response have been characterized and possess varying phenotypes and levels of resistance to 2,4-D or IAA (Leyser et al., Nature 364: 161-164, 1993; Ruegger et al., Genes Dev 12: 198-207, 1998; Nagpal et al., Plant Physiol 123: 563-573, 2000). However, their chemical resistance profile to picolinate auxins has not been previously established.

The mutant axr1-3 is defective in the rubinylation mechanism required to activate SCF complexes. This mutant had a high level of resistance to DAS534 as well as to 2,4-D (FIGS. 5B and 5C) and so there was no indication of significant chemical selectivity between these two auxin classes in this mutant. The axr1-3 mutant was also very resistant to picloram (160-fold). The relative degree of resistance of axr1-3 to the picolinate auxins was higher than that of Group 1 and Group 2 mutants indicating that this mutation has a more profound overall effect on auxinic responses. This is consistent with its general role in the activation of SCF complexes (Schwechheimer et al., Plant Cell. 14(10):2553-2563, 2002).

Mutants containing lesions in the F-box protein tir1 have significantly lower levels of resistance to 2,4-D than axr1 (FIG. 5C) suggesting that additional SCF complex components may also be involved in the 2,4-D response (Ruegger et al., Genes Dev 12: 198-207, 1998; Dharmasiri et al., Nature 435:441-445, 2005). It was presently found that the modest level of resistance of tir1-1 to DAS534 was approximately equivalent to that of 2,4-D thus the marked chemical selectivity observed with the Group 1 and 2 mutants was not apparent with this mutant. The tir1-1 mutant was slightly more resistant to picloram than DAS534 but this resistance is considerably less than the resistance of either Group 1 or Group 2 mutants to this compound. The resistance levels of tir1-1 and axr1-3 to 2,4-D in our study were similar to those previously described (Estelle & Somerville, Mol Gen Genet. 206: 200-206, 1987; Ruegger et al., Genes Dev 12: 198-207, 1998), validating that the results from the subject assay system are comparable to previous work using slightly different assay methodologies.

AXR2 is one of the short-lived AUX/IAA transcriptional regulators targeted for SCF-mediated ubiquitination and mutations in these loci have been found to confer a dominant 2,4-D resistance phenotype (Wilson et al., Mol Gen Genet. 222: 377-383, 1990; Nagpal et al., Plant Physiol 123: 563-573, 2000). The roots of axr2 are agravitropic and elongated relative to wild type, corresponding to a loss of auxin regulation. The level of resistance of axr2-1 to DAS534 was similar to that found with 2,4-D and picloram and so there was no marked chemical specificity in resistance.

In summary, none of the three previously described auxin-resistant mutants that were tested showed the differential pattern of no or low resistance to 2,4-D and high levels of resistance to picolinate auxins that we identified in the Group 1 and 2 mutants from our picolinate auxin resistance screen.

Example 5 Resistance Phenotype of AFB5 SGT1B Double Mutants

Mutations in either AFB5 or SGT1b cause similar levels of resistance to DAS534. Plants containing homozygous mutations in both AFB5 and SGT1b were generated to determine if the level of resistance to DAS534 was similar or increased over that of the single mutant lines. Genomic DNA was isolated from ninety-five F2 plants generated from a cross of R009 and R051. The At5g49980 (AFB5) and At4g11260 (SGT1b) genes were amplified by PCR and evaluated by DNA sequence analysis for mutations. Eight plants containing double mutations were identified and three of them were compared with the single mutant parental lines for resistance to DAS534, picloram and 2,4-D. The single and double mutants exhibited similar levels of resistance (5 to 10-fold, data not shown), thus the resistance mechanisms in afb5 and sgt1b are not additive. The double mutants also exhibited no obvious deleterious phenotype in growth or fertility, similar to the single mutants. These data therefore suggest that AFB5 and SGT1b are involved in the same response pathway to DAS534.

Example 6 Functional Assay for AFB5

A biochemical pull-down assay to monitor the picolinate auxin-response of AFB5 is constructed using the methods described in Dharmasiri et al. (Curr. Biol. 13:1418-1422, 2003). However, plant extracts for the assays are made from transgenic Arabidopsis afb5 plants expressing myc-tagged AFB5 rather than tir1 plants expressing TIR1-myc. The recovery of AFB5-myc is monitored by immunoblotting with anti-c-myc antibody. Test compounds are added into the assay mixture and the reduction in recovery of AFB5-Myc is monitored.

Example 7 Ligand-Binding Assay for AFB5

A biochemical assay to monitor ligand-binding by AFB5 is constructed using the methods described in Dharmasiri et al. (Nature 435:441-445, 2005) and Kepinski and Leyser (Nature, 435:446-451, 2005). However, plant extracts for the assays are made from transgenic Arabidopsis afb5 plants expressing myc-tagged AFB5 rather than tir1 plants expressing TIR1-myc. Also [³H]-picloram, [³H]DAS534 or other tritiated picolinate auxin is used as the radioligand instead of [³H]IAA or [³H]2,4-D. Test compounds are added into the assay mixture and the displacement of binding of tritiated picolinate auxin is monitored.

Example 8 Sequence Comparisons and Identification of Additional Homologs

BLAST searches of the NCBI databases using the AtAFB5 sequence identified six AFBs in the Arabidopsis genome (AtTIR1, AtAFB1-5), 4 AFB homologs from the rice (Oryza sativa) genome, and a homolog of AFB5 from Populus. All of these sequences were aligned using CLUSTALW within the AlignX module of Vector NTI.

From this CLUSTAL alignment, a phylogenetic analysis was performed using the neighbor-joining method in MEGA3.1 (S Kumar et al. (2004) Briefings in Bioinformatics 5:150-163) (% bootstrap values from 1000 iterations are shown). As illustrated in FIG. 7, this shows that AFB5, AFB4, and 4 other related AFBs (Os NP 912552, Os XP 507533, Pt AAK16647) are distinct from previously characterized TIR1 and 5 TIR1-related AFBs (AtAFB14g03190, AtTIR1At3g62980, Os XP 493919, Os CA D40545, AtAFB2 3g26810, and AtAFB3 1g12820). Members of the TIR1 group share at least 42% amino acid identity with all other members of that group.

Across the entire proteins, AFB4 and AFB5 share about 80% amino acid identity with each other. Members of the AFB4 and AFB5 group all have at least 54% identity with all other members of the group. The protein sequence from Populus has about 70% identity with AFB4 and about 73% identity with AFB5. All members of this group are considered to be within, and usable according to, the subject invention. The mRNA and protein sequences, respectively, of the four AFB5 homologs are attached as SEQ ID NOS: 7 and 8 (Oryza sativa (rice) (Genbank entry gi:34902411), SEQ ID NOS: 9 and 10 (Oryza sativa (rice) (Genbank entry gi:51979369), and SEQ ID NOS:11 and 12 (from Populus).

Example 9 Resistance of AFB5 Mutant to Foliar Application of Picolinate Auxin Herbicides

Arabidopsis seedlings were grown for two weeks in a growth chamber (23° C.; continuous light at 120-150 μE m⁻² sec⁻¹), then taken to the greenhouse for three days after which plants were sprayed with herbicide using a track-sprayer to deliver the appropriate rate. Plants were then grown in the greenhouse for 12 days (22° C. under supplemented light with a 14 h: 10 h light-dark cycle) prior to photography and evaluation. A foliar spray application of picloram or aminopyralid at 200 g/ha on wild type Col-0 Arabidopsis plants growing in the greenhouse produced profound morphological effects and severely inhibited plant growth, whereas the applications had minimal effect on the Group 1 mutant R009 (FIG. 8A-8C). This is in contrast to the effect of 2,4-D which induces auxinic symptoms and growth reduction to a similar extent on both wild type and mutant plants at 50 g/ha. Thus the chemical selectivity of resistance seen in seedling plate assays is maintained in adult plants with foliar exposure to the auxin herbicides.

ADDITIONAL REFERENCES

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We claim:
 1. A method of identifying an herbicidal compound that binds with an AFB4 protein, the AFB4 protein comprising a polypeptide comprising an amino acid sequence having at least 95% amino acid sequence identity with SEQ ID NO: 6, the method comprising: contacting the AFB4 protein with a test compound; assaying the AFB4 protein for bound compound; and screening the compound for herbicidal activity.
 2. The method of claim 1, wherein the AFB4 protein comprises a polypeptide comprising an amino acid sequence set forth as SEQ ID NO:
 6. 3. The method of claim 1, wherein the AFB4 protein consists of a polypeptide having an amino acid sequence set forth as SEQ ID NO:
 6. 4. The method of claim 1, wherein the herbicidal compound is an auxin herbicidal compound.
 5. The method of claim 1, wherein the herbicidal compound is a picolinate auxin herbicidal compound. 